Security Target COMMON CRITERIA DOCUMENTS | Version 1.0 MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC) Machine Readable Travel Document with “ICAO Application”, Basic Access Control Certification-ID: BSI-DSZ-CC-1034-V2    Public Version MaskTech International GmbH | Nordostpark 45 | Nuernberg | www.masktech.com | +49 (0)911 95 51 49-0 Security Target Contents 1 ST Introduction (ASE_INT.1) 3 1.1 ST Reference and TOE Reference . . . . . . . . . . . . . . . . . . . . . . . . 3 1.2 TOE Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2 Conformance Claims (ASE_CCL.1) 8 2.1 CC Conformance Claim . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 2.2 PP Reference . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 2.3 Package Claim . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 2.4 Conformance Claim Rationale . . . . . . . . . . . . . . . . . . . . . . . . . . 9 3 Security Problem Definition (ASE_SPD.1) 10 3.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 3.2 Assumptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 3.3 Threats . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 3.4 Organizational Security Policies . . . . . . . . . . . . . . . . . . . . . . . . . 15 4 Security Objectives (ASE_OBJ.2) 17 4.1 Security Objectives for the TOE . . . . . . . . . . . . . . . . . . . . . . . . . 17 4.2 Security Objectives for the Operational Environment . . . . . . . . . . . . . 20 4.3 Security Objective Rationale . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 5 Extended Components Definition (ASE_ECD.1) 25 6 Security Requirements (ASE_REQ.2) 26 6.1 Security Functional Requirements for the TOE . . . . . . . . . . . . . . . . . 27 6.2 Security Assurance Requirements for the TOE . . . . . . . . . . . . . . . . . 43 6.3 Security Requirements Rationale . . . . . . . . . . . . . . . . . . . . . . . . 44 7 TOE Summary Specification (ASE_TSS.1) 52 7.1 TOE Security Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 1 Security Target 7.2 Assurance Measures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 7.3 TOE Summary Specification Rationale . . . . . . . . . . . . . . . . . . . . . 58 7.4 Statement of Compatibility . . . . . . . . . . . . . . . . . . . . . . . . . . . 61 8 Glossary and Acronyms 66 9 Revision History 75 10 Contact 76 A Overview Cryptographic Algorithms 77 MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 2 Security Target 1 ST Introduction (ASE_INT.1) 1.1 ST Reference and TOE Reference Title Security Target – Machine Readable Travel Document with “ICAO Ap- plication”, Basic Access Control, MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC) Version 1.0, 2021-04-09 Editors Gudrun Schürer Compliant to Common Criteria Protection Profile - Machine Readable Travel Docu- ment with “ICAO Application”, Basic Access Control, version 1.10, BSI- CC-PP-0055 CC Version 3.1 (Revision 5) Assurance Level The assurance level for this ST is EAL4 augmented TOE name MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), operation system for secure passports TOE Hardware Infineon Technologies AG SLE78CLFX400VPHM/BPHM/7PHM (M7892), dual interface Smartcard IC (see also section 1.2) TOE version MTCOS Pro 2.5 EAC with PACE Keywords ICAO, machine readable travel document, basic access control 1.2 TOE Overview This security target defines the security objectives and requirements for the contactless /contact1 chip of machine readable travel documents (MRTD) based on the requirements and recommendations of the International Civil Aviation Organization (ICAO). It addresses the advanced security methods Basic Access Control in the ’ICAO Doc 9303’ [ICAO_9303]. MTCOSProisafullyinteroperablemulti-applicationsmartcardoperatingsystemcompli- ant to ISO/IEC 7816 [ISO_7816]. It provides public and secret key cryptography and supports also other applications like e-purses, health insurance cards and access control. TheoperatingsystemsoftwareisimplementedontheSLE78CLFX400VPHM/BPHM/7PHM (M7892) secure dual-interface controller of Infineon Technologies AG with the design steps ’D11’ (produced in Dresden, [IFX_ST-SLE78-D11-G12]), ’G12’ (produced in Tainan, 1 Both interfaces provide the same functionality and are thus taken as one single product in this ST. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 3 Security Target [IFX_ST-SLE78-D11-G12]) and ’P11’ (produced in East Fishkill, [IFX_ST-SLE78-P11]). The design steps differ only in the production site of the chip. All design steps are thus taken as one configuration. Furthermore, the TOE uses three derivatives of the chip with the sales codes: • SLE78CLFX400VPHM, • SLE78CLFX400BPHM and • SLE78CLFX4007PHM These derivatives differ only in the antenna capacity (input capacitance of the RF inter- face) of the module. This difference is not security-relevant, thus all derivatives are taken as one configuration. Chip and cryptographic library are certified according to CC EAL6 aug- mented compliant to the Protection Profile BSI-CC-PP-0084-2014 [CC_PP-0084]). The TOE consists of software and hardware. TOE Definition The Target of Evaluation (TOE) is the contactless /contact integrated circuit chip of machine readable travel documents (MRTD’s chip) programmed according to the Logical Data Struc- ture (LDS) [ICAO_9303] and providing Basic Access Control according to the ’ICAO 9303’ [ICAO_9303]. The TOE comprises of • the circuitry of the MRTD’s chip (the integrated circuit, IC) • the IC Dedicated Software with the parts IC Dedicated Test Software and IC Dedicated Support Software • the IC Embedded Software (operating system) • the MRTD application • the associated guidance documentation [AGD, MT_Manual] TheTOEisbasedonISO/IEC7816[ISO_7816]commandsandisintendedtobeusedinside a MRTD as storage of the digital data and supports Basic Access Control and Extended Access Control. It provides following services for MRTDs: • Storage of the MRTD data, e.g. data groups and signature • Organization of the data in a file system as dedicated and elementary files • Mutual Authenticate and Secure Messaging as specified in [ICAO_9303] for Basic Ac- cess Control • Contactless communication according to [ISO_14443] • Protection of the privacy of the passport holder with functions like random UID and Basic Access Control TOE Usage and Security Features for Operational Use State or organization issues MRTD to be used by the holder for international travel. The trav- eler presents a MRTD to the Inspection System to prove his or her identity. The MRTD in con- text of this Security Target contains (i) visual (eye readable) biographical data and portrait MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 4 Security Target of the holder, (ii) a separate data summary (MRZ data) for visual and machine reading using OCR methods in the Machine Readable Zone (MRZ) and (iii) data elements on the MRTD’s chip according to LDS [ICAO_9303] for contactless or contact based machine reading. The authentication of the traveler is based on (i) the possession of a valid MRTD personalized for a holder with the claimed identity as given on the biographical data page and (ii) biometrics using the reference data stored in the MRTD. The issuing State or Organization ensures the authenticity of the data of genuine MRTD’s. The receiving State trusts a genuine MRTD of an issuing State or Organization. For this security target the MRTD is viewed as unit of the physical MRTD as travel document in form of paper, plastic and chip. It presents visual readable data including (but not limited to) personal data of the MRTD holder 1. the biographical data on the biographical data page of the passport book 2. the printed data in the Machine Readable Zone (MRZ) 3. the printed portrait the logical MRTD as data of the MRTD holder stored according to the Logical Data Struc- ture [ICAO_9303] as specified by ICAO on the contactless /contact integrated circuit. It presents contactless or contact based readable data including (but not limited to) per- sonal data of the MRTD holder 1. the digital Machine Readable Zone Data (digital MRZ data, EF.DG1) 2. the digitized portraits (EF.DG2) 3. the biometric reference data of finger(s) (EF.DG3) or iris image(s) (EF.DG4) or both 4. the other data according to LDS (EF.DG5 to EF.DG16) 5. the Document Security Object The issuing State or Organization implements security features of the MRTD to maintain the authenticity and integrity of the MRTD and their data. The MRTD as the passport book and the MRTD’s chip is uniquely identified by the document number. The physical MRTD is protected by physical security measures (e.g. watermark on paper, securityprinting), logical(e.g. authenticationkeysoftheMRTD’schip)andorganizationalse- curity measures (e.g. control of materials, personalization procedures) [ICAO_9303]. These security measures include the binding of the MRTD’s chip to the passport book. The logical MRTD is protected in authenticity and integrity by a digital signature created by the document signer acting for the issuing State or Organization and the security features of the MRTD’s chip. The ICAO defines the baseline security methods Passive Authentication and the optional advanced security methods Basic Access Control to the logical MRTD, Active Authentication of the MRTD’s chip, Extended Access Control to and the Data Encryption of sensitive biomet- rics as optional security measure in the ICAO Doc 9303 [ICAO_9303]. The Passive Authenti- cation Mechanism and the Data Encryption are performed completely and independently of the TOE by the TOE environment. This Security Target addresses the protection of the logical MRTD (i) in integrity by write- only-onceaccesscontrolandbyphysicalmeans,and(ii)inconfidentialitybytheBasicAccess Control Mechanism. This Security Target does not address the Active Authentication and the Extended Access Control as optional security mechanisms. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 5 Security Target Note 1: Extended Access Control and Active Authentication has been evaluated and certified in procedure BSI-DSZ-CC1033-V2. The Basic Access Control is a security feature which is mandatory supported by the TOE. The inspection system (i) reads optically the MRTD, (ii) authenticates itself as inspection sys- tem by means of Document Basic Access Keys. After successful authentication of the inspec- tion system the MRTD’s chip provides read access to the logical MRTD by means of private communication (Secure Messaging) with this inspection system [ICAO_9303], normative ap- pendix 5. TOE Life Cycle The TOE life cycle is described in terms of the four life cycle phases. With respect to [CC_PP-0084], the TOE life cycle is additionally subdivided into 7 step. Phase 1: Development (Step 1) The TOE is developed in phase 1. The IC developer de- velops the integrated circuit, the IC Dedicated Software and the guidance documenta- tion associated with these TOE components. (Step 2) The software developer uses the guidance documentation for the integrated circuit and the guidance documentation for relevant parts of the IC Dedicated Soft- ware and develops the IC Embedded Software (operating system), the MRTD applica- tion and the guidance documentation associated with these TOE components. The manufacturing documentation of the IC including the IC Dedicated Software and the Embedded Software in the non-volatile non-programmable memories (FLASH) is securely delivered to the IC manufacturer. The IC Embedded Software in the non- volatile programmable memories, the MRTD application and the guidance documen- tation is securely delivered to the MRTD manufacturer. Phase 2: Manufacturing (Step 3) In a first step the TOE integrated circuit is produced containing the travel document’s chip Dedicated Software and conditionally the parts of the travel document’s chip Embedded Software in the non-volatile non- programmable memories (FLASH). Infineon Technologies AG writes the IC Identifica- tion Data onto the chip to control the IC as travel document material during the IC manufacturing and the delivery process to the MRTD manufacturer. Conditionally, Infineon Technologies AG adds the parts of the IC Embedded Software inthenon-volatileprogrammablememories(FLASH)anddeactivatestheFlashLoader permanently. The IC is securely delivered from Infineon Technologies AG to the MRTD manufacturer. Alternatively, MASKTECH INTERNATIONAL GMBH in the role of the Manufacturer writes the Embedded Software in the non-volatile non-programmable memories (FLASH) of the chip and deactivates the Flash Loader permanently. (Step 4) See Inlay production below Note 2: The inlay production including the application of the antenna is not part of the TOE. (Step 5) The MRTD manufacturer (i) creates the MRTD application and (ii) equips MRTD’s chips with pre-personalization Data. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 6 Security Target Note 3: For file based operating systems, the creation of the application implies the creation of MF and ICAO.DF. Note 4: The role of the Manufacturer performing initialization and pre-personalization in the Card Issuing phase is taken over by MASKTECH INTERNATIONAL GMBH, Linxens (Thailand) Co Ltd. (see [SC_Linxens]), HID Global Malaysia (see [SC_HID_MY]) and Infi- neon Technologies AG (see [IFX_ST-SLE78-D11-G12, IFX_ST-SLE78-P11]). Note 5: In the case of Infineon Technologies AG being the Manufacturer performing initialization and pre-personalization, the deactivation of the Flash Loader can also be performed after the initialization/pre-personalization step. The pre-personalized MRTD together with the IC Identifier is securely delivered from the MRTD manufacturer to the Personalization Agent. The MRTD manufacturer also provides the relevant parts of the guidance documentation to the Personalization Agent. (Inlay production) The MRTD manufacturer combines the IC with hardware for the contactless /contact interface in the passport book. The inlay production including the application of the antenna is NOT part of the TOE and takes part after the delivery. Phase 3: Personalization of the MRTD (Step 6) The personalization of the MRTD in- cludes (i) the survey of the MRTD holder’s biographical data, (ii) the enrollment of the MRTD holder biometric reference data (i.e. the digitized portraits and the optional bio- metric reference data), (iii) the printing of the visual readable data onto the physical MRTD, (iv) the writing of the TOE User Data and TSF Data into the logical MRTD and (v) configuration of the TSF if necessary. The step (iv) is performed by the Personalization Agent and includes but is not limited to the creation of (i) the digital MRZ data (EF.DG1), (ii) the digitized portrait (EF.DG2), and (iii) the Document security object. The signing of the Document security object by the Document signer [ICAO_9303] fi- nalizesthepersonalizationofthegenuineMRTDfortheMRTDholder. Thepersonalized MRTD (together with appropriate guidance for TOE use if necessary) is handed over to the MRTD holder for operational use. Phase 4: Operational Use (Step 7) The TOE is used as MRTD chip by the traveler and the Inspection Systems in the “Operational Use” phase. The user data can be read according to the security policy of the issuing State or Organization and can be used according to the security policy of the issuing State but they can never be modified. Non-TOE Hardware/Software/Firmware Required by the TOE There is no explicit non-TOE hardware, software or firmware required by the TOE to perform itsclaimedsecurityfeatures. TheTOEisdefinedtocomprisethechipandthecompleteoper- ating system and application. Note, the inlay holding the chip as well as the antenna and the booklet (holding the printed MRZ) are needed to represent a complete MRTD, nevertheless these parts are not inevitable for the secure operation of the TOE. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 7 Security Target 2 Conformance Claims (ASE_CCL.1) 2.1 CC Conformance Claim This security target claims conformance to • Common Criteria for Information Technology Security Evaluation, Part 1: Intro- duction and General Model; CCMB-2017-04-001, Version 3.1 Revision 5, April 2017 [CC_Part1] • Common Criteria for Information Technology Security Evaluation, Part 2: Secu- rity Functional Components; CCMB-2017-04-002, Version 3.1 Revision 5, April 2017 [CC_Part2] • Common Criteria for Information Technology Security Evaluation, Part 3: Secu- rity Assurance Components; CCMB-2017-04-003, Version 3.1 Revision 5, April 2017 [CC_Part3] as follows • Part 2 extended • Part 3 conformant The • Common Methodology for Information Technology Security Evaluation, Evaluation Methodology; CCMB-2017-04-004, Version 3.1 Revision 5, April 2017 [CC_PartEM] has to be taken into account. 2.2 PP Reference The conformance of this ST to the Common Criteria Protection Profile - Machine Read- able Travel Document with “ICAO Application”, Basic Access Control, BSI-CC-PP-0055 [CC_PP-0055] is claimed. 2.3 Package Claim The assurance level for the TOE is CC EAL4 augmented with ALC_DVS.2 defined in CC part 3 [CC_Part3]. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 8 Security Target 2.4 Conformance Claim Rationale According section 2.2 this ST claims conformance to [CC_PP-0055]. “Application notes” in- cluded in the PP are only resumed, if they are of interest for the reader. In this case they are renamed to “Note” and renumbered consecutively. All ther deviations are listed in Table 2.1 below. None of the changes causes a conflict between ST and PP. Assurance Component Description ASE_INT.1 (see sec. 1) The TOE is described in detail in compliance to the PP. A number of Manufacturers for initialization and pre-personalization is included. ASE_CCL.1 (see sec. 2) Conformance to CC Parts version 3.1 revision 5 (PP: revision 1 or 2, respectively) is claimed. ASE_SPD.1 (see sec. 3) No significant changes. ASE_OBJ.2 (see sec. 4) No significant changes. ASE_ECD.1 (see sec. 5) The component has not been resumed, but the reference to the according chapter of [CC_PP-0055] is given. ASE_REQ.2 (see sec. 6) In order to meet [BSI_AIS31] • FCS_RND.1 has been changed according to [CC_PP-0084] (FCS_RNG.1) Table 2.1: Conformance claim rationale. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 9 Security Target 3 Security Problem Definition (ASE_SPD.1) 3.1 Introduction Assets The assets to be protected by the TOE include the User Data on the MRTD’s chip. Logical MRTD Data The logical MRTD data consists of the EF.COM, EF.DG1 to EF.DG16 (with different security needs) and the Document Security Object EF.SOD according to LDS [ICAO_9303]. These data are user data of the TOE. The EF.COM lists the existing elementary files (EF) with the user data. The EF.DG1 to EF.DG13 and EF.DG 16 contain personal data of the MRTD holder. The Chip Authentication Public Key (EF.DG 14) is used by the Inspection System for the Chip Authentication and the Active Authentica- tion Public Key (EF.DG15) for Active Authentication. The EF.SOD is used by the inspec- tion system for Passive Authentication of the logical MRTD. Due to interoperability reasons the ’ICAO Doc 9303’ [ICAO_9303] specifies only the BAC mechanisms with resistance against enhanced basic attack potential granting access to • Logical MRTD standard User Data (i.e. Personal Data) of the MRTD holder (EF.DG1, EF.DG2, EF.DG5 to EF.DG13, EF.DG16) • Chip Authentication Public Key in EF.DG14 • Active Authentication Public Key in EF.DG15 • Document Security Object (SOD) in EF.SOD • Common data in EF.COM A sensitive asset is the following more general one. Authenticity of the MRTD’s chip The authenticity of the MRTD’s chip personalized by the issuing State or Organization for the MRTD holder is used by the traveler to prove his possession of a genuine MRTD. Subjects This Security Target considers the following subjects: MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.010 Security Target Manufacturer The generic term for the IC Manufacturer producing the integrated cir- cuit and the MRTD Manufacturer completing the IC to the MRTD’s chip. The Manufac- turer is the default user of the TOE during the phase 2 Manufacturing. The TOE does not distinguish between the users IC Manufacturer and MRTD Manufacturer using this role Manufacturer. During pre-personalization the MRTD manufacturer (so-called Pre- Personalization Agent) prepares the TOE for the personalization, e.g. creation of data files. Personalization Agent The agent is acting on behalf of the issuing State or Organization to personalize the MRTD for the holder by some or all of the following activities: (i) es- tablishing the identity of the holder for the biographic data in the MRTD, (ii) enrolling the biometric reference data of the MRTD holder i.e. the portrait, the encoded finger image(s) and/or the encoded iris image(s), (iii) writing these data on the physical and logical MRTD for the holder as defined for global, international and national interop- erability, (iv) writing the initial TSF data and (v) signing the Document Security Object defined in [ICAO_9303]. Terminal A terminal is any technical system communicating with the TOE through the contactless/contact interface. Inspection system (IS) A technical system used by the border control officer of the re- ceiving State (i) examining an MRTD presented by the traveler and verifying its authen- ticity and (ii) verifying the traveler as MRTD holder. The Basic Inspection System (BIS) (i) contains a terminal for the contactless or contact based communication with the MRTD’s chip, (ii) implements the terminals part of the Basic Access Control Mechanism and (iii) gets the authorization to read the logical MRTD under the Basic Access Control by optical reading the MRTD or other parts of the passport book providing this infor- mation. The General Inspection System (GIS) is a Basic Inspection System which im- plements additionally the Chip Authentication Mechanism. The Extended Inspection System (EIS) in addition to the General Inspection System (i) implements the Termi- nal Authentication Protocol and (ii) is authorized by the issuing State or Organization through the Document Verifier of the receiving State to read the sensitive biometric reference data. The security attributes of the EIS are defined of the Inspection System Certificates. MRTD Holder The rightful holder of the MRTD for whom the issuing State or Organiza- tion personalized the MRTD. Traveler Person presenting the MRTD to the Inspection System and claiming the iden- tity of the MRTD holder. Attacker A threat agent trying (i) to identify and to trace the movement of the MRTD’s chip remotely (i.e. without knowing or optically reading the printed MRZ data), (ii) to readortomanipulatethelogicalMRTDwithoutauthorization, or(iii)toforgeagenuine MRTD. Note: An impostor is attacking the inspection system as TOE IT environment indepen- dent on using a genuine, counterfeit or forged MRTD. Therefore the impostor may use results of successful attacks against the TOE but the attack itself is not relevant for the TOE. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 11 Security Target 3.2 Assumptions The assumptions describe the security aspects of the environment in which the TOE will be used or is intended to be used. A.MRTD_Manufact (MRTD manufacturing on steps 4 to 6) It is assumed that appropriate functionality testing of the MRTD is used. It is assumed that security procedures are used during all manufacturing and test operations to maintain confidentiality and integrity of the MRTD and of its manufacturing and test data(topreventanypossiblecopy, modification, retention, theftorunauthorizeduse). A.MRTD_Delivery (MRTD delivery during steps 4 to 6) Procedures shall guarantee the control of the TOE delivery and storage process and conformance to its objectives: • Procedures shall ensure protection of TOE material/information under delivery and storage. • Procedures shall ensure that corrective actions are taken in case of improper op- eration in the delivery process and storage. • Procedures shall ensure that people dealing with the procedure for delivery have got the required skill. A.Pers_Agent (Personalization of the MRTD’s chip) The Personalization Agent ensures the correctness of (i) the logical MRTD with respect to the MRTD holder, (ii) the Document Basic Access Keys, (iii) the Chip Authentication Public Key (EF.DG14) if stored on the MRTD’s chip, and (iv) the Document Signer Pub- lic Key Certificate (if stored on the MRTD’s chip). The Personalization Agent signs the Document Security Object. The Personalization Agent bears the Personalization Agent Authentication to authenticate himself to the TOE by symmetric cryptographic mech- anisms. A.Insp_Sys (Inspection Systems for global interoperability) The Inspection System is used by the border control officer of the receiving State (i) ex- aminingan MRTDpresentedby thetravelerand verifyingitsauthenticity and(ii)verify- ing the traveler as MRTD holder. The Basic Inspection System for global interoperabil- ity (i) includes the Country Signing Public Key and the Document Signer Public Key of each issuing State or Organization, and (ii) implements the terminal part of the Basic Access Control [ICAO_9303]. The Basic Inspection System reads the logical MRTD un- der Basic Access Control and performs the Passive Authentication to verify the logical MRTD. A.BAC-Keys (Cryptographic quality of Basic Access Control Keys) The Document Basic Access Control Keys being generated and imported by the issuing State or Organization have to provide sufficient cryptographic strength. As a conse- quence of the ’ICAO Doc 9303’ [ICAO_9303], the Document Basic Access Control Keys are derived from a defined subset of the individual printed MRZ data. It has to be ensured that these data provide sufficient entropy to withstand any attack based on the decision that the inspection system has to derive Document Access Keys from the printed MRZ data with enhanced basic attack potential. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 12 Security Target 3.3 Threats This section describes the threats to be averted by the TOE independently or in collaboration with its IT environment. These threats result from the TOE method of use in the operational environment and the assets stored in or protected by the TOE. The TOE in collaboration with its IT environment shall avert the threats as specified be- low. T.Chip_ID (Identification of MRTD’s chip) Adverse action An attacker trying to trace the movement of the MRTD by identi- fying remotely the MRTD’s chip by establishing or listening to communications through the contactless communication interface. Threat agent Having enhanced basic attack potential, not knowing the optically readable MRZ data printed on the MRTD data page in advance. Asset Anonymity of user. T.Skimming (Skimming the logical MRTD) Adverse action An attacker imitates an Inspection System trying to establish a communication to read the logical MRTD or parts of it via the contactless com- munication channel of the TOE. Threat agent Having enhanced basic attack potential, not knowing the optically readable MRZ data printed on the MRTD data page in advance. Asset Confidentiality of logical MRTD data. T.Eavesdropping (Eavesdropping to the communication between TOE and Inspec- tion System) Adverse action An attacker is listening to an existing communication between the MRTD’s chip and an inspection system to gain the logical MRTD or parts of it. The inspection system uses the MRZ data printed on the MRTD data page but the at- tacker does not know these data in advance. Threat agent Having enhanced basic attack potential, not knowing the optically readable MRZ data printed on the MRTD data page in advance. Asset Confidentiality of logical MRTD data. T.Forgery (Forgery of data on MRTD’s chip) Adverse action An attacker alters fraudulently the complete stored logical MRTD or any part of it including its security related data in order to deceive on an in- spection system by means of the changed MRTD holder’s identity or biometric reference data. This threat comprises several attack scenarios of MRTD forgery. The attacker may alter the biographical data on the biographical data page of the passport book, in the printed MRZ and in the digital MRZ to claim another identity of the traveler. The attacker may alter the printed portrait and the digitized portrait to overcome the visual inspection of the inspection officer and the automated biometric au- thentication mechanism by face recognition. The attacker may alter the biomet- ric reference data to defeat automated biometric authentication mechanism of MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 13 Security Target the inspection system. The attacker may combine data groups of different logi- cal MRTDs to create a new forged MRTD, e.g. the attacker writes the digitized por- trait and optional biometric reference finger data read from the logical MRTD of a traveler into another MRTD’s chip leaving their digital MRZ unchanged to claim the identity of the holder this MRTD. The attacker may also copy the complete unchanged logical MRTD to another contactless chip. Threat agent Having enhanced basic attack potential, being in possession of one or more legitimate MRTDs. Asset Authenticity of logical MRTD data. The TOE shall avert the threats as specified below. T.Abuse-Func (Abuse of Functionality) Adverse action An attacker may use functions of the TOE which shall not be used in “Operational Use” phase in order (i) to manipulate User Data, (ii) to manipulate (explore, bypass, deactivate or change) security features or functions of the TOE or (iii) to disclose or to manipulate TSF Data. This threat addresses the misuse of the functions for the initialization and the personalization in the operational state after delivery to MRTD holder. Threat agent Having enhanced basic attack potential, being in possession of a le- gitimate MRTD. Asset Confidentiality and authenticity of logical MRTD and TSF data, correctness of TSF. T.Information_Leakage (Information Leakage from MRTD’s chip) Adverse action An attacker may exploit information which is leaked from the TOE during its usage in order to disclose confidential TSF data. The information leak- age may be inherent in the normal operation or caused by the attacker. Leakage may occur through emanations, variations in power consumption, I/O characteristics, clock frequency, or by changes in processing time requirements. This leakage may be interpreted as a covert channel transmission but is more closely related to measurement of operating parameters which may be derived either from measurements of the contactless interface (emanation) or direct measurements (by contact to the chip still available even for a contactless chip) and can then be related to the specific operation being performed. Examples are the Differential Electromagnetic Analysis (DEMA) and the Differential Power Anal- ysis (DPA). Moreover the attacker may try actively to enforce information leakage by fault injection (e.g. Differential Fault Analysis). Threat agent Having enhanced basic attack potential, being in possession of a le- gitimate MRTD. Asset Confidentiality of logical MRTD and TSF data. T.Phys-Tamper (Physical Tampering) Adverse action An attacker may perform physical probing of the MRTD’s chip in order (i) to disclose TSF Data, or (ii) to disclose/reconstruct the MRTD’s chip Em- bedded Software. An attacker may physically modify the MRTD’s chip in order to (i) modify security features or functions of the MRTD’s chip, (ii) modify security MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.014 Security Target functions of the MRTD’s chip Embedded Software, (iii) modify User Data or (iv) to modify TSF data. The physical tampering may be focused directly on the disclosure or manipula- tion of TOE User Data (e.g. the biometric reference data for the Inspection Sys- tem) or TSF Data (e.g. authentication key of the MRTD’s chip) or indirectly by preparation of the TOE to following attack methods by modification of security features (e.g. to enable information leakage through power analysis). Physical tampering requires direct interaction with the MRTD’s chip internals. Techniques commonly employed in IC failure analysis and IC reverse engineering efforts may be used. Before that, the hardware security mechanisms and layout characteris- tics need to be identified. Determination of software design including treatment of User Data and TSF Data may also be a pre-requisite. The modification may re- sult in the deactivation of a security function. Changes of circuitry or data can be permanent or temporary. Threat agent Having enhanced basic attack potential, being in possession of a le- gitimate MRTD. Asset Confidentiality and authenticity of logical MRTD and TSF data, correctness of TSF. T.Malfunction (Malfunction due to Environmental Stress) Adverse action An attacker may cause a malfunction of TSF or of the MRTD’s chip Embedded Software by applying environmental stress in order to (i) deactivate or modify security features or functions of the TOE or (ii) circumvent, deactivate or modify security functions of the MRTD’s chip Embedded Software. This may be achieved e.g. by operating the MRTD’s chip outside the normal oper- ating conditions, exploiting errors in the MRTD’s chip Embedded Software or mis- using administration function. To exploit these vulnerabilities an attacker needs information about the functional operation. Threat agent Having enhanced basic attack potential, being in possession of a le- gitimate MRTD. Asset Confidentiality and authenticity of logical MRTD and TSF data, correctness of TSF. 3.4 Organizational Security Policies The TOE shall comply with the following Organizational Security Policies (OSP) as security rules, procedures, practices, or guidelines imposed by an organization upon its operations (see CC part 1, sec. 3.2 [CC_Part1]). P.Manufact (Manufacturing of the MRTD’s chip) The Initialization Data are written by the IC Manufacturer to identify the IC uniquely. The MRTD Manufacturer writes the Pre-personalization Data which contains at least the Personalization Agent Key. P.Personalization (Personalization of the MRTD by issuing State or Organization only) MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 15 Security Target The issuing State or Organization guarantees the correctness of the biographical data, the printed portrait and the digitized portrait, the biometric reference data and other data of the logical MRTD with respect to the MRTD holder. The personalization of the MRTD for the holder is performed by an agent authorized by the issuing State or Orga- nization only. P.Personal_Data (Personal data protection policy) The biographical data and their summary printed in the MRZ and stored on the MRTD’s chip(EF.DG1), theprintedportraitandthedigitizedportrait(EF.DG2), thebiometricref- erence data of finger(s) (EF.DG3), the biometric reference data of iris image(s) (EF.DG4)1 and data according to LDS (EF.DG5 to EF.DG13, EF.DG16) stored on the MRTD’s chip are personal data of the MRTD holder. These data groups are intended to be used only with agreement of the MRTD holder by Inspection Systems to which the MRTD is pre- sented. The MRTD’s chip shall provide the possibility for the Basic Access Control to allow read access to these data only for terminals successfully authenticated based on knowledge of the Document Basic Access Keys as defined in [ICAO_9303]. Note 6: The organizational security policy P.Personal_Data is drawn from the ICAO ’ICAO Doc 9303’ [ICAO_9303]. Note that the Document Basic Access Key is defined by the TOE environment and loaded to the TOE by the Personalization Agent. 1 Note, that EF.DG3 and EF.DG4 are only readable after successful EAC authentication not being covered by BSI-CC-PP-0055 [CC_PP-0055] MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.016 Security Target 4 Security Objectives (ASE_OBJ.2) This chapter describes the security objectives for the TOE and the security objectives for the TOE environment. The security objectives for the TOE environment are separated into secu- rity objectives for the development and production environment and security objectives for the operational environment. 4.1 Security Objectives for the TOE ThissectiondescribesthesecurityobjectivesfortheTOEaddressingtheaspectsofidentified threats to be countered by the TOE and organizational security policies to be met by the TOE. OT.AC_Pers (Access Control for Personalization of logical MRTD) The TOE must ensure that the logical MRTD data in EF.DG1 to EF.DG16, the Document security object according to LDS [ICAO_9303] and the TSF data can be written by au- thorized Personalization Agents only. The logical MRTD data in EF.DG1 to EF.DG16 and the TSF data may be written only during and cannot be changed after its personal- ization. The Document security object can be updated by authorized Personalization Agents if data in the data groups EF.DG3 to EF.DG16 are added. Note 7: The OT.AC_Pers implies that 1. the data of the LDS groups written during personalization for MRTD holder (at leastEF.DG1andEF.DG2)cannotbechangedbywriteaccessafterpersonalization 2. the Personalization Agents may (i) add (fill) data into the LDS data groups not written yet, and (ii) update and sign the Document Security Object accordingly. The support for adding data in the “Operational Use” phase is optional. OT.Data_Int (Integrity of personal data) The TOE must ensure the integrity of the logical MRTD stored on the MRTD’s chip against physical manipulation and unauthorized writing. The TOE must ensure that the inspection system is able to detect any modification of the transmitted logical MRTD data. OT.Data_Conf (Confidentiality of personal data) The TOE must ensure the confidentiality of the logical MRTD data groups EF.DG1 to EF.DG16. Read access to EF.DG1 to EF.DG16 is granted to terminals successfully authen- ticated as Personalization Agent. Read access to EF.DG1, EF.DG2 and EF.DG5 to EF.DG16 is granted to terminals successfully authenticated as Basic Inspection System. The Ba- sic Inspection System shall authenticate itself by means of the Basic Access Control MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 17 Security Target based on knowledge of the Document Basic Access Key. The TOE must ensure the con- fidentiality of the logical MRTD data during their transmission to the Basic Inspection System. Note 8: The traveler grants the authorization for reading the personal data in EF.DG1, EF.DG2 and EF.DG5 to EF.DG16 to the Inspection System by presenting the MRTD. The MRTD’s chip shall provide read access to these data for terminals successfully authen- ticated by means of the Basic Access Control based on knowledge of the Document Basic Access Keys. This Security Objective requires the TOE to ensure the strength of the security function Basic Access Control Authentication. The Document Basic Access Keys are derived from the MRZ data defined by the TOE environment and are loaded into the TOE by the Personalization Agent. Therefore the sufficient quality of these keys has to result from the MRZ data’s entropy. Any attack based on decision of the ’ICAO Doc 9303’ [ICAO_9303] that the Inspection System derives Document Basic Ac- cess is ensured by OE.BAC-Keys. Note that the authorization for reading the biometric datainEF.DG3andEF.DG4isonlygrantedaftersuccessfulEnhancedAccessControlnot covered by this Security Target, but that of BSI-DSZ-CC-1033-V2. Thus the read access must be prevented even in case of a successful BAC Authentication. OT.Identification (Identification and Authentication of the TOE) The TOE must provide means to store IC Identification and Pre-Personalization Data in its non-volatile memory. The IC Identification Data must provide a unique iden- tification of the IC during phase 2 Manufacturing and phase 3 Personalization of the MRTD. The storage of the Pre-Personalization Data includes writing of the Personaliza- tion Agent Key(s). In phase 4 “Operational Use” the TOE shall identify itself only to a successful authen- ticated Basic Inspection System or Personalization Agent. Note 9: The TOE Security Objective OT.Identification addresses security features of the TOE to support the Life Cycle security in the Manufacturing and Personalization phases. The IC Identification Data are used for TOE identification in phase 2 and for traceability and/or to secure shipment of the TOE from phase 2 into the phase 3. This Security Objective addresses security features of the TOE to be used by the TOE manu- facturing. In the phase 4 the TOE is identified by the Document Number as part of the printed and digital MRZ. This Security Objective forbids the output of any other IC (e.g. integrated circuit card serial number ICCSN) or MRTD identifier through the contact- less/contact interface before successful authentication as Basic Inspection System or as Personalization Agent. The following TOE Security Objectives address the protection provided by the MRTD’s chip independent on the TOE environment. OT.Prot_Abuse-Func (Protection against Abuse of Functionality) After delivery of the TOE to the MRTD Holder, the TOE must prevent the abuse of test andsupportfunctionsthatmaybemaliciouslyusedto(i)disclosecriticalUserData, (ii) manipulatecriticalUserDataoftheICEmbeddedSoftware, (iii)manipulateSoft-coded MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.018 Security Target IC Embedded Software or (iv) bypass, deactivate, change or explore security features or functions of the TOE. Details of the relevant attack scenarios depend, for instance, on the capabilities of the Test Features provided by the IC Dedicated Test Software which are not specified here. OT.Prot_Inf_Leak (Protection against Information Leakage) The TOE must provide protection against disclosure of confidential TSF data stored and/or processed in the MRTD’s chip • by measurement and analysis of the shape and amplitude of signals or the time between events found by measuring signals on the electromagnetic field, power consumption, clock, or I/O lines and • by forcing a malfunction of the TOE and/or • by a physical manipulation of the TOE Note 10: This Security Objective pertains to measurements with subsequent complex signal processing due to normal operation of the TOE or operations enforced by an attacker. Details correspond to an analysis of attack scenarios which is not given here. OT.Prot_Phys-Tamper (Protection against Physical Tampering) The TOE must provide protection of the confidentiality and integrity of the User Data, the TSF Data, and the MRTD’s chip Embedded Software. This includes protection against attacks with enhanced basic attack potential by means of • measuring through galvanic contacts which is direct physical probing on the chips surface except on pads being bonded (using standard tools for measuring voltage and current) or • measuring not using galvanic contacts but other types of physical interaction be- tweencharges(usingtoolsusedinsolid-statephysicsresearchandICfailureanal- ysis) • manipulation of the hardware and its security features, as well as • controlled manipulation of memory contents (User Data, TSF Data) with a prior • reverse-engineering to understand the design and its properties and functions. T.Prot_Malfunction (Protection against Malfunctions) The TOE must ensure its correct operation. The TOE must prevent its operation out- side the normal operating conditions where reliability and secure operation has not been proven or tested. This is to prevent errors. The environmental conditions may include external energy (esp. electromagnetic) fields, voltage (on any contacts), clock frequency, or temperature. Note 11: A malfunction of the TOE may also be caused using a direct interaction with elements on the chip surface. This is considered as being a manipulation (refer to the objective OT.Prot_Phys-Tamper) provided that detailed knowledge about the TOE’s in- ternals. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.019 Security Target 4.2 Security Objectives for the Operational Environment Issuing State or Organization The Issuing State or Organization will implement the following security objectives of the TOE environment. OE.MRTD_Manufact (Protection of the MRTD Manufacturing) Appropriate functionality testing of the TOE shall be used in step 4 to 6. During all manufacturing and test operations, security procedures shall be used through phases 4, 5 and 6 to maintain confidentiality and integrity of the TOE and its manufacturing and test data. OE.MRTD_Delivery (Protection of the MRTD delivery) ProceduresshallensureprotectionofTOEmaterial/informationunderdeliveryinclud- ing the following objectives: • Non-disclosure of any security relevant information • Identification of the element under delivery • Meet confidentiality rules (confidentiality level, transmittal form, reception ac- knowledgment) • Physical protection to prevent external damage • Secure storage and handling procedures (including rejected TOE’s) • Traceability of TOE during delivery including the following parameters: – Origin and shipment details – Reception, reception acknowledgment – Location material/information Proceduresshallensurethatcorrectiveactionsaretakenincaseofimproperoperation in the delivery process (including if applicable any non-conformance to the confiden- tiality convention) and highlight all non-conformance to this process. Procedures shall ensure that people (shipping department, carrier, reception depart- ment) dealing with the procedure for delivery have got the required skill, training and knowledge to meet the procedure requirements and be able to act fully in accordance with the above expectations. OE.Personalization (Personalization of logical MRTD) The issuing State or Organization must ensure that the Personalization Agents acting on behalf of the issuing State or Organization (i) establish the correct identity of the holder and create biographical data for the MRTD, (ii) enroll the biometric reference data of the MRTD holder i.e. the portrait, the encoded finger image(s) and/or the en- coded iris image(s) and (iii) personalize the MRTD for the holder together with the de- finedphysicalandlogicalsecuritymeasurestoprotecttheconfidentialityandintegrity of these data. OE.Pass_Auth_Sign (Authentication of logical MRTD by Signature) The issuing State or Organization must (i) generate a cryptographic secure Country Signing CA Key Pair, (ii) ensure the secrecy of the Country Signing CA Private Key and MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.020 Security Target sign Document Signer Certificates in a secure operational environment, and (iii) dis- tribute the Certificate of the Country Signing CA Public Key to receiving States and organizations maintaining its authenticity and integrity. The issuing State or orga- nization must (i) generate a cryptographic secure Document Signer Key Pair and en- sure the secrecy of the Document Signer Private Keys, (ii) sign Document Security Ob- jects of genuine MRTD in a secure operational environment only and (iii) distribute the Certificate of the Document Signing Public Key to receiving States and organizations. The digital signature in the Document Security Object relates to all data in the data in EF.DG1 to EF.DG16 if stored in the LDS according to [ICAO_9303]. OE.BAC-Keys (Cryptographic quality of Basic Access Control Keys) The Document Basic Access Control Keys being generated and imported by the issuing State or Organization have to provide sufficient cryptographic strength. As a conse- quence of the ’ICAO Doc 9303’ [ICAO_9303] the Document Basic Access Control Keys are derived from a defined subset of the individual printed MRZ data. It has to be en- sured that these data provide sufficient entropy to withstand any attack based on the decision that the inspection system has to derive Document Basic Access Keys from the printed MRZ data with enhanced basic attack potential. Receiving State or organization The receiving State or Organization will implement the following security objectives of the TOE environment. OE.Exam_MRTD (Examination of the MRTD passport book) The Inspection System of the receiving State must examine the MRTD presented by the traveler to verify its authenticity by means of the physical security measures and to detect any manipulation of the physical MRTD. The Basic Inspection System for global interoperability (i) includes the Country Signing Public Key and the Document Signer Public Key of each issuing State or Organization, and (ii) implements the terminal part of the Basic Access Control [ICAO_9303]. OE.Passive_Auth_Verif (Verification by Passive Authentication) ThebordercontrolofficerofthereceivingStateusestheInspectionSystemtoverifythe traveler as MRTD holder. The Inspection Systems must have successfully verified the signature of Document Security Objects and the integrity data elements of the logical MRTD before they are used. The receiving States and Organizations must manage the Country Signing CA Public Key and the Document Signer Public Key maintaining their authenticity and availability in all Inspection Systems. OE.Prot_Logical_MRTD (Protection of data of the logical MRTD) The Inspection System of the receiving State or Organization ensures the confidential- ity and integrity of the data read from the logical MRTD. The receiving State examining the logical MRTD being under Basic Access Control will use inspection systems which implement the terminal part of the Basic Access Control and use the secure messaging with fresh generated keys for the protection of the transmitted data (i.e. Basic Inspec- tion Systems). MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 21 Security Target 4.3 Security Objective Rationale Table 4.1 provides an overview for security objectives coverage. OT.AC_Pers OT.Data_Int OT.Data_Conf OT.Identification OT.Prot_Abuse-Func OT.Prot_Inf_Leak OT.Prot_Phys-Tamper OT.Prot_Malfunction OE.MRTD_Manufact OE.MRTD_Delivery OE.Personalization OE.Pass_Auth_Sign OE.BAC-Keys OE.Exam_MRTD OE.Passive_Auth_Verif OE.Prot_Logical_MRTD T.Chip-ID x x T.Skimming x x T.Eavesdropping x T.Forgery x x x x x x T.Abuse-Func x x T.Information_Leakage x T.Phys-Tamper x T.Malfunction x P.Manufact x P.Personalization x x x P.Personal_Data x x A.MRTD_Manufact x A.MRTD_Delivery x A.Pers_Agent x A.Insp_Sys x x A.BAC-Keys x Table 4.1: Security Objective Rationale The OSP P.Manufact “Manufacturing ofthe MRTD’schip” requiresa uniqueidentification of the IC by means of the Initialization Data and the writing of the Pre-personalization Data as being fulfilled by OT.Identification. The OSP P.Personalization “Personalization of the MRTD by issuing State or Organiza- tion only” addresses the (i) the enrollment of the logical MRTD by the Personalization Agent as described in the security objective for the TOE environment OE.Personalization “Per- sonalization of logical MRTD”, and (ii) the access control for the user data and TSF data as described by the security objective OT.AC_Pers “Access Control for Personalization of log- ical MRTD”. Note the manufacturer equips the TOE with the Personalization Agent Key(s) according to OT.Identification “Identification and Authentication of the TOE”. The security objective OT.AC_Pers limits the management of TSF data and the management of TSF to the Personalization Agent. The OSP P.Personal_Data “Personal data protection policy” requires the TOE (i) to sup- MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.022 Security Target port the protection of the confidentiality of the logical MRTD by means of the Basic Access Control and (ii) enforce the access control for reading as decided by the issuing State or Or- ganization. This policy is implemented by the security objectives OT.Data_Int “Integrity of personal data” describing the unconditional protection of the integrity of the stored data and during transmission. The security objective OT.Data_Conf “Confidentiality of personal data” describes the protection of the confidentiality. The threat T.Chip_ID “Identification of MRTD’s chip” addresses the trace of the MRTD movement by identifying remotely the MRTD’s chip through the contactless communication interface. This threat is countered as described by the security objective OT.Identification by Basic Access Control using sufficiently strong derived keys as required by the security objective for the environment OE.BAC-Keys. The threat T.Skimming “Skimming digital MRZ data or the digital portrait” and T.Eavesdropping “Eavesdropping to the communication between TOE and inspection sys- tem” address the reading of the logical MRTD trough the contactless interface or listening the communication between the MRTD’s chip and a terminal. This threat is countered by the security objective OT.Data_Conf “Confidentiality of personal data” through Basic Ac- cess Control using sufficiently strong derived keys as required by the security objective for the environment OE.BAC-Keys. The threat T.Forgery “Forgery of data on MRTD’s chip” addresses the fraudulent alter- ationofthecompletestoredlogicalMRTDoranypartofit. ThesecurityobjectiveOT.AC_Pers “Access Control for Personalization of logical MRTD” requires the TOE to limit the write ac- cess for the logical MRTD to the trustworthy Personalization Agent (cf. OE.Personalization). The TOE will protect the integrity of the stored logical MRTD according the security objec- tiveOT.Data_Int“Integrityofpersonaldata”andOT.Prot_Phys-Tamper“Protectionagainst Physical Tampering”. The examination of the presented MRTD passport book according to OE.Exam_MRTD “Examination of the MRTD passport book” shall ensure that passport book does not contain a sensitive contactless chip which may present the complete un- changed logical MRTD. The TOE environment will detect partly forged logical MRTD data by means of digital signature which will be created according to OE.Pass_Auth_Sign “Au- thentication of logical MRTD by Signature” and verified by the inspection system according OE.Passive_Auth_Verif “Verification by Passive Authentication”. The threat T.Abuse-Func “Abuse of Functionality” addresses attacks of misusing MRTD’s functionality to disable or bypass the TSFs. The security objective for the TOE OT.Prot_Abuse-Func “Protection against abuse of functionality” ensures that the usage of functions which may not be used in the “Operational Use” phase is effectively prevented. Therefore attacks intending to abuse functionality in order to disclose or manipulate criti- cal (User) Data or to affect the TOE in such a way that security features or TOE’s functions may be bypassed, deactivated, changed or explored shall be effectively countered. Ad- ditionally this objective is supported by the security objective for the TOE environment: OE.Personalization “Personalization of logical MRTD” ensuring that the TOE security func- tions for the initialization and the personalization are disabled and the security functions for the operational state after delivery to MRTD holder are enabled according to the intended use of the TOE. The threats T.Information_Leakage “Information Leakage from MRTD’s chip”, T.Phys- Tamper “Physical Tampering” and T.Malfunction “Malfunction due to Environmental MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.023 Security Target Stress” are typical for integrated circuits like smart cards under direct attack with high at- tack potential. The protection of the TOE against these threats is addressed by the directly related security objectives OT.Prot_Inf_Leak “Protection against Information Leakage”, OT.Prot_Phys-Tamper “Protection against Physical Tampering” and OT.Prot_Malfunction “Protection against Malfunctions”. The assumption A.MRTD_Manufact “MRTD manufacturing on step 4 to 6” is covered by the security objective for the TOE environment OE.MRTD_Manufact “Protection of the MRTD Manufacturing” that requires to use security procedures during all manufacturing steps. The assumption A.MRTD_Delivery “MRTD delivery during step 4 to 6” is covered by the security objective for the TOE environment OE.MRTD_Delivery “Protection of the MRTD de- livery” that requires to use security procedures during delivery steps of the MRTD. The assumption A.Pers_Agent “Personalization of the MRTD’s chip” is covered by the security objective for the TOE environment OE.Personalization “Personalization of logical MRTD” including the enrollment, the protection with digital signature and the storage of the MRTD holder personal data. The examination of the MRTD passport book addressed by the assumption A.Insp_Sys “Inspection Systems for global interoperability” is covered by the security objectives for the TOE environment OE.Exam_MRTD “Examination of the MRTD passport book”. The security objectives for the TOE environment OE.Prot_Logical_MRTD “Protection of data from the logical MRTD” require the Inspection System to protect the logical MRTD data during the transmission and the internal handling. The assumption A.BAC-Keys “Cryptographic quality of Basic Access Control Keys” is di- rectly covered by the security objective for the TOE environment OE.BAC-Keys “Crypto- graphic quality of Basic Access Control Keys” ensuring the sufficient key quality to be pro- vided by the issuing State or Organization. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.024 Security Target 5 Extended Components Definition (ASE_ECD.1) This Security Target uses the components defined in chapter 5 of[CC_PP-0055]. The security requirement FCS_RND.1 has been changed according to the security requirement FCS_RNG.1 defined in [CC_PP-0084] to meet [BSI_AIS31]. No other components are used. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.025 Security Target 6 Security Requirements (ASE_REQ.2) The CC allows several operations to be performed on functional requirements; refine- ment, selection, assignment, and iteration are defined in paragraph C.4 of Part 1 of the CC [CC_Part1]. Each of these operations is used in this ST. The refinement operation is used to add detail to a requirement, and thus further re- stricts a requirement. Refinement of security requirements is denoted by the word “refine- ment” in bold text and the added/changed words are in bold text. In cases where words from a CC requirement were deleted, a separate attachment indicates the words that were removed. The selection operation is used to select one or more options provided by the CC in stating a requirement. Selections that have been made by the PP authors are denoted as underlined text and the original text of the component is given by a footnote. Selections filled in by the ST author are denoted as double-underlined text. The assignment operation is used to assign a specific value to an unspecified parameter, such as the length of a password. Assignments that have been made by the PP authors are denoted by showing as underlined text and the original text of the component is given by a footnote. Assignments filled in by the ST author are denoted as double-underlined text. The iteration operation is used when a component is repeated with varying operations. Iteration is denoted by showing a slash “/”, and the iteration indicator after the component identifier. The definition of the subjects “Manufacturer”, “Personalization Agent”, “Extended In- spection System”, “Country Verifying Certification Authority”, “Document Verifier” and “Ter- minal” used in the following chapter is given in section 3.1. Note, that all these subjects are acting for homonymous external entities. All used objects are defined either in chap- ter 8 or in the following table. The operations “write”, “modify”, “read” and “ disable read access” are used in accordance with the general linguistic usage. The operations “store”, “create”, “transmit”, “receive”, “establishcommunicationchannel”, “authenticate”and“re- authenticate” are originally taken from [CC_Part2]. The operation “load” is synonymous to “import” used in [CC_Part2]. Definition of security attributes Terminal authentication status none (any Terminal) default role (i.e. without authorization after start-up) MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.026 Security Target Basic Inspection System terminal is authenticated as Basic Inspection System after successful Authentication in accordance with the definition in rule 2 of FIA_UAU.5.2. Personalization Agent Terminal is authenticated as Personalization Agent af- ter successful Authentication in accordance with the definition in rule 1 of FIA_UAU.5.2. 6.1 Security Functional Requirements for the TOE This section on security functional requirements for the TOE is divided into subsections fol- lowing the main security functionality. 6.1.1 Class FAU Security Audit The TOE shall meet the requirement “Audit storage (FAU_SAS.1)” as specified below (Com- mon Criteria Part 2 [CC_Part2] extended). FAU_SAS.1 Audit storage Hierarchical to: No other components. Dependencies: No dependencies. FAU_SAS.1.1 The TSF shall provide the Manufacturer with the capability to store the IC Identification Data in the audit records. Note 12: The Manufacturer role is the default user identity assumed by the TOE in the phase 2 Manufacturing. The IC manufacturer and the MRTD manufacturer in the Manufacturer role writetheInitializationDataand/orPre-personalizationDataasTSFDataoftheTOE.Theaudit records are write-only-once data of the MRTD’s chip (see FMT_MTD.1/INI_DIS). 6.1.2 Class Cryptographic Support (FCS) The TOE shall meet the requirement “Cryptographic key generation (FCS_CKM.1)” as speci- fied below (Common Criteria Part 2 [CC_Part2]). The iterations are caused by different cryp- tographic key generation algorithms to be implemented and keys to be generated by the TOE. FCS_CKM.1 Cryptographic key generation – Generation of Document Basic Ac- cess Keys by the TOE Hierarchical to: No other components. Dependencies: [FCS_CKM.2 Cryptographic key distribution or FCS_COP.1 Cryptographic operation] FCS_CKM.4 Cryptographic key destruction MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.027 Security Target FCS_CKM.1.1 The TSF shall generate cryptographic keys in accordance with a spec- ified cryptographic key generation algorithm Document Basic Access Key Derivation Algorithm and specified cryptographic key sizes 112 bit that meet the following: [ICAO_9303], normative appendix 5. Note 13: The TOE is equipped with the Document Basic Access Key generated and down- loaded by the Personalization Agent. The Basic Access Control Authentication Protocol de- scribed in [ICAO_9303], normative appendix 5, A5.2, produces agreed parameters to gener- atetheTriple-DESkeyandtheRetail-MACmessageauthenticationkeysforsecuremessaging by the algorithm in [ICAO_9303], Normative appendix A5.1. The algorithm uses the random number RND.ICC generated by TSF as required by FCS_RND.1. The TOE shall meet the requirement “Cryptographic key destruction (FCS_CKM.4)” as spec- ified below (Common Criteria Part 2 [CC_Part2]). FCS_CKM.4 Cryptographic key destruction Hierarchical to: No other components. Dependencies: [FDP_ITC.1 Import of user data without security attributes, or FDP_ITC.2 Import of user data with security attributes, or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4.1 TheTSFshalldestroycryptographickeysinaccordancewithaspecified cryptographic key destruction method physical deletion of key value by overwriting with zero or random numbers that meets the following: none. Note 14: The TOE shall destroy the Triple-DES encryption key and the Retail-MAC message authentication keys for secure messaging. 6.1.2.1 Cryptographic Operation (FCS_COP.1) The TOE shall meet the requirement “Cryptographic operation (FCS_COP.1)” as specified below (Common Criteria Part 2 [CC_Part2]). The iterations are caused by different crypto- graphic algorithms to be implemented by the TOE. FCS_COP.1/SHA Cryptographic operation – Hash for Key Derivation by MRTD Hierarchical to: No other components. Dependencies: [FDP_ITC.1 Import of user data without security attributes, or FDP_ITC.2 Import of user data with security attributes, or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4 Cryptographic key destruction FCS_COP.1.1/SHA The TSF shall perform hashing in accordance with a specified crypto- graphic algorithm SHA-1 and cryptographic key sizes none that meet the following: [FIPS_180-4], in detail sections 6.1 and 6.2. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.028 Security Target FCS_COP.1/ENC Cryptographic operation – Encryption / Decryption Triple DES Hierarchical to: No other components. Dependencies: [FDP_ITC.1 Import of user data without security attributes, or FDP_ITC.2 Import of user data with security attributes, or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4 Cryptographic key destruction FCS_COP.1.1/ENC The TSF shall perform Secure Messaging (BAC) - encryption and decryption in accordance with a specified cryptographic algorithm Triple-DES in CBC mode and cryptographic key size 112 bit that meet the following: [NIST_SP800-67] and [ISO_10116], sec. 7 . Note15: ThisSFR requirestheTOE toimplement thecryptographicprimitive forsecuremes- saging with encryption of the transmitted data. The keys are agreed between the TOE and the terminal as part of the Basic Access Control Authentication Mechanism according to the FCS_CKM.1 and FIA_UAU.4. [ICAO_9303] defines two key 3DES with a keysize of 112 bits to be used for Basic Access Control. Keep in mind that this method does not meet the security level of 100 bits recommended by [BSI_TR-02102-1]. FCS_COP.1/AUTH Cryptographic operation – Authentication Hierarchical to: No other components. Dependencies: [FDP_ITC.1 Import of user data without security attributes, or FDP_ITC.2 Import of user data with security attributes, or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4 Cryptographic key destruction FCS_COP.1.1/AUTH The TSF shall perform symmetric authentication - encryption and decryptioninaccordancewithaspecifiedcryptographicalgorithmAES in CBC mode and cryptographic key sizes 128 bit that meet the follow- ing: [ISO_18013-3] Annex B, [ISO_10116], sec. 7, and [FIPS_197]. Note 16: This SFR requires the TOE to implement the cryptographic primitive for authenti- cation attempt of a terminal as Personalization Agent by means of the symmetric authenti- cation mechanism (cf. FIA_UAU.4). Informative: The usage of Secure Messaging for the personalization in accordance with the cryptographic algorithm AES in CBC mode and cryptographic key size 128 bit is within the scope of certification BSI-DSZ-CC-1033-V2. FCS_COP.1/MAC Cryptographic operation – Retail MAC Hierarchical to: No other components. Dependencies: [FDP_ITC.1 Import of user data without security attributes, or FDP_ITC.2 Import of user data with security attributes, or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4 Cryptographic key destruction MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.029 Security Target FCS_COP.1.1/MAC The TSF shall perform Secure Messaging - message authentication code in accordance with a specified cryptographic algorithm Retail MAC and cryptographic key sizes 112 bit that meet the following: [NIST_SP800-67] and [ISO_9797-1], MAC Algorithm 3 (Retail-MAC), in section 7.4. Note 17: This SFR requires the TOE to implement the cryptographic primitive for secure messaging with message authentication code over the transmitted data. The key is agreed between the TSF by the Basic Access Control Authentication Mechanism according to the FCS_CKM.1 and FIA_UAU.4. [ICAO_9303] defines two key 3DES with a keysize of 112 bits to be used for Basic Access Control. Keep in mind that this method does not meet the security level of 100 bits recommended by [BSI_TR-02102-1]. 6.1.2.2 Random Number Generation (FCS_RND.1) The TOE shall meet the requirement “Quality metric for random numbers (FCS_RND.1)” as specified below (Common Criteria Part 2 extended [CC_Part2]). FCS_RND.1 Random number generation (Class PTG.3) Hierarchical to: No other components. Dependencies: No dependencies. FCS_RND.1.1 The TSF shall provide a [hybrid physical] random number generator that implements: (PTG.3.1) A total failure test detects a total failure of entropy source immediately when the RNG has started. When a total failure is detected, no random numbers will be output. (PTG.3.2) If a total failure of the entropy source occurs while the RNG is being operated, the RNG prevents the output of any internal random number that depends on some raw random numbers that have been generated after the total failure of the entropy source. (PTG.3.3) The online test shall detect non-tolerable statistical defects of the raw random number sequence (i) immediately when the RNG has started, and (ii) while the RNG is being operated. The TSF must not output any random numbers before the power-up online test and the seeding of the DRG.3 post-processing algorithm have been finished successfully or when a defect has been detected. (PTG.3.4) The online test procedure shall be effective to detect non-tolerable weaknesses of the random numbers soon. (PTG.3.5) The online test procedure checks the raw random number sequence. It is triggered continuously. The online test is suitable for detecting nontolerable statistical defects of the statistical properties of the raw random numbers within an acceptable period of time. (PTG.3.6) The algorithmic post-processing algorithm belongs to Class DRG.3 with cryptographic state transition function and cryptographic output function, and the output data rate of the post-processing algorithm shall not exceed its input data rate. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.030 Security Target FCS_RND.1.2 The TSF shall provide octets of bits that meet: (PTG.3.7) Statistical test suites cannot practically distinguish the internal random numbers from output sequences of an ideal RNG. The internal random numbers must pass test procedure A none.1 (PTG.3.8) The internal random numbers shall use PTRNG of class PTG.2 as random source for the postprocessing. Note 18: This SFR requires the TOE to generate random numbers used for the authentication protocols as required by FIA_UAU.4. Note 19: This SFR has been changed according to [CC_PP-0084] (FCS_RNG.1) and justified in [KiSch-RNG] chapter 3 (PTG.3) to meet [BSI_AIS31]. 6.1.3 Class FIA Identification and Authentication Note 20: Table 6.1 provides an overview on the authentication mechanisms used. Name SFR for the TOE Algorithms and key sizes according to [ICAO_9303] and [BSI_TR-03110] Basic Access Control Authentication Mechanism FIA_AFL.1, FIA_UAU.4, FIA_UAU.6 Triple-DES, 112 bit keys; Retail-MAC, 112 bit keys Symmetric Authentication Mechanism for Personalization Agents FIA_UAU.4 AES, 128 bit keys Table 6.1: Overview on authentication SFR The TOE shall meet the requirement “Timing of identification (FIA_UID.1)” as specified below (Common Criteria Part 2 [CC_Part2]). FIA_UID.1 Timing of identification Hierarchical to: No other components. Dependencies: No dependencies. FIA_UID.1.1 The TSF shall allow 1. to read the Initialization Data in phase 2 “Manufacturing” 2. to read the random identifier in phase 3 “Personalization of the MRTD” 3. to read the random identifier in phase 4 “Operational Use” on behalf of the user to be performed before the user is identified. FIA_UID.1.2 The TSF shall require each user to be successfully identified before al- lowing any other TSF-mediated actions on behalf of that user. 1 See [KiSch-RNG] Section 2.4.4. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 31 Security Target Note21: TheICmanufacturerandtheMRTDmanufacturerwritetheinitializationdataand/or pre-personalization data in the audit records of the IC during the phase 2 “Manufacturing”. The audit records can be written only in the phase 2 “Manufacturing of the TOE”. At this time the Manufacturer is the only user role available for the TOE. The MRTD manufacturer creates the user role Personalization Agent for transition from phase 2 to phase 3 “Personalization of theMRTD”. TheusersinrolePersonalizationAgentidentifythemselvesbymeansofselecting the authentication key. After personalization in the phase 3 (i.e. writing the digital MRZ and the Document Basic Access Keys) the user role Basic Inspection System is created by writing the Document Basic Access Keys. The Basic Inspection System is identified as default user after power up or reset of the TOE i.e. the TOE will use the Document Basic Access Key to authenticate the user as Basic Inspection System. Note22: Inthe“operationaluse”phasetheMRTDmustnotallowanybodytoreadtheICCSN, the MRTD identifier or any other unique identification before the user is authenticated as Basic Inspection System (cf. T.Chip_ID). Note that the terminal and the MRTD’s chip use a randomly chosen identifier for the communication channel to allow the terminal to commu- nicate with more then one RFID. This identifier will not violate the OT.Identification. The TOE shall meet the requirement “Timing of authentication (FIA_UAU.1)” as specified be- low (Common Criteria Part 2 [CC_Part2]). FIA_UAU.1 Timing of authentication Hierarchical to: No other components. Dependencies: FIA_UID.1 Timing of identification. FIA_UAU.1.1 The TSF shall allow 1. to read the Initialization Data in phase 2 “Manufacturing” 2. to read the random identifier in phase 3 “Personalization of the MRTD” 3. to read the random identifier in phase 4 “Operational Use” on behalf of the user to be performed before the user is authenticated. FIA_UAU.1.2 The TSF shall require each user to be successfully authenticated before allowing any other TSF-mediated actions on behalf of that user. Note 23: The Basic Inspection System and the Personalization Agent authenticate them- selves. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.032 Security Target The TOE shall meet the requirements of “Single-use authentication mechanisms (FIA_UAU.4)” as specified below (Common Criteria Part 2 [CC_Part2]). FIA_UAU.4 Single-use authentication mechanisms - Single-use authentication of the Terminal by the TOE Hierarchical to: No other components. Dependencies: No dependencies. FIA_UAU.4.1 The TSF shall prevent reuse of authentication data related to 1. Basic Access Control Authentication Mechanism 2. Authentication Mechanism based on Triple-DES and AES Note 24: The authentication mechanisms use a challenge freshly and randomly generated by the TOE to prevent reuse of a response generated by a terminal in a successful authenti- cation attempt. Note 25: The Basic Access Control Mechanism is a mutual device authentication mecha- nism defined in [ICAO_9303]. In the first step the terminal authenticates itself to the MRTD’s chip and the MRTD’s chip authenticates to the terminal in the second step. In this second step the MRTD’s chip provides the terminal with a challenge-response-pair which allows a unique identification of the MRTD’s chip with some probability depending on the entropy of the Document Basic Access Keys. Therefore the TOE shall stop further communications if the terminal is not successfully authenticated in the first step of the protocol to fulfill the security objective OT.Identification and to prevent T.Chip_ID. The TOE shall meet the requirement “Multiple authentication mechanisms (FIA_UAU.5)” as specified below (Common Criteria Part 2 [CC_Part2]). FIA_UAU.5 Multiple authentication mechanisms Hierarchical to: No other components. Dependencies: No dependencies. FIA_UAU.5.1 The TSF shall provide 1. Basic Access Control Authentication Mechanism 2. Symmetric Authentication Mechanism based on Triple-DES and AES to support user authentication. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.033 Security Target FIA_UAU.5.2 The TSF shall authenticate any user’s claimed identity according to the following rules: 1. The TOE accepts the authentication attempt as Personalization Agent by one of the following mechanisms (a) the Basic Access Control Authentication Mechanism with Personalization Agent Keys (b) the Symmetric Authentication Mechanism with Personalization Agent Key 2. The TOE accepts the authentication attempt as Basic Inspection System only by means of the Basic Access Control Authentication Mechanism with the Document Basic Access Keys Note 26: Because the ’Common Criteria Protection Profile Machine Readable Travel Doc- ument with “ICAO Application”, Extended Access Control’ [CC_PP-0056] should also be ful- filledthePersonalizationAgentshouldnotbeauthenticatedbyusingtheBACorthesymmet- ric authentication mechanism as they base on the two-key Triple-DES, but using the Termi- nal Authentication Protocol using the Personalization Key (cf. [CC_PP-0056] FIA_UAU.5.2). Note 27: The Basic Access Control Mechanism includes the Secure Messaging for all com- mands exchanged after successful authentication of the inspection system. The Basic In- spection System may use the Basic Access Control Authentication Mechanism with the Doc- ument Basic Access Keys. The TOE shall meet the requirement “Re-authenticating (FIA_UAU.6)” as specified below (Common Criteria Part 2 [CC_Part2]). FIA_UAU.6 Re-authenticating – Re-authenticating of Terminal by the TOE Hierarchical to: No other components. Dependencies: No dependencies. FIA_UAU.6.1 The TSF shall re-authenticate the user under the conditions each command sent to the TOE during a BAC mechanism based communication after successful authentication of the terminal with Basic Access Control Authentication Mechanism. Note 28: The Basic Access Control Mechanism specified in [ICAO_9303] includes the Se- cure Messaging for all commands exchanged after successful authentication of the Inspec- tion System. The TOE checks by Secure Messaging in MAC_ENC mode each command based on Retail-MAC whether it was sent by the successfully authenticated terminal (see FCS_COP.1/MAC for further details). The TOE does not execute any command with incorrect message authentication code. Therefore the TOE re-authenticates the user for each received command and accepts only those commands received from the previously authenticated BAC user. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.034 Security Target Note 29: Note that in case the TOE should also fulfill [CC_PP-0056] the BAC communica- tion might be followed by a Chip Authentication mechanism establishing a new secure mes- saging that is distinct from the BAC based communication. In this case the condition in FIA_UAU.6 above should not contradict to the option that commands are sent to the TOE that are no longer meeting the BAC communication but are protected by a more secure com- munication channel established after a more advanced authentication process. The TOE shall meet the requirement “Authentication failure handling (FIA_AFL.6)” as speci- fied below (Common Criteria Part 2 [CC_Part2]). FIA_AFL.1 Authentication failure handling Hierarchical to: No other components. Dependencies: FIA_UAU.1 Timing of authentication FIA_AFL.1.1 The TSF shall detect when 1 unsuccessful authentication attempt oc- curs related to BAC authentication. FIA_AFL.1.2 When the defined number of unsuccessful authentication attempts has been met, the TSF shall wait for an administrator configurable time of at least 1 second between the reception of the authentication command and its processing. Note 30: The TSF shall detect when an administrator configurable positive integer within range of acceptable values 1 to 10 consecutive unsuccessful authentication attempts occur related to BAC authentication protocol. When the defined number of unsuccessful authen- tication attempts has been met or surpassed, the TSF shall wait for an administrator config- urabletimebetweenthereceivingtheterminalchallengeeIFDandsendingtheTSFresponse eICC during the BAC authentication attempts. The terminal challenge eIFD and the TSF re- sponse eICC are described in [BSI_TR-03110], Appendix C. The refinement by inclusion of the word “consecutive” allows the TSF to return to normal operation of the BAC authentication protocol (without time out) after successful run of the BAC authentication protocol. The un- successful authentication attempt shall be stored non-volatile in the TOE thus the “consec- utive unsuccessful authentication attempts” are count independent on power-on sessions but reset to zero after successful authentication only. Note 31: The Personalization Agent chooses from a list provided by the Manufacturer the configuration of the authentication failure handling. 6.1.4 Class FDP User Data Protection The TOE shall meet the requirement “Subset access control (FDP_ACC.1)” as specified below (Common Criteria Part 2 [CC_Part2]). MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.035 Security Target FDP_ACC.1 Subset access control Hierarchical to: No other components. Dependencies: FDP_ACF.1 Security attribute based access control FDP_ACC.1.1 TheTSFshallenforcetheBasicAccessControlSFPonterminalsgaining write, read and modification access to data in the EF.COM, EF.SOD, EF.DG1 to EF.DG16 of the logical MRTD. TheTOEshallmeettherequirement“Securityattributebasedaccesscontrol(FDP_ACF.1)”as specified below (Common Criteria Part 2 [CC_Part2]). FDP_ACF.1 Security attribute based access control Hierarchical to: No other components. Dependencies: FDP_ACC.1 Subset access control FMT_MSA.3 Static attribute initialization FDP_ACF.1.1 The TSF shall enforce the Basic Access Control SFP to objects based on the following: 1. Subjects: (a) Personalization Agent (b) Basic Inspection System (c) Terminal 2. Objects: (a) data EF.DG1 to EF.DG16 of the logical MRTD (b) data in EF.COM (c) data in EF.SOD 3. Security attributes: (a) authentication status of terminals. FDP_ACF.1.2 The TSF shall enforce the following rules to determine if an operation among controlled subjects and controlled objects is allowed: 1. the successfully authenticated Personalization Agent is allowed to write and to read the data of the EF.COM, EF.SOD, EF.DG1 to EF.DG16 of the logical MRTD 2. the successfully authenticated Basic Inspection System is allowed to read the data in EF.COM, EF.SOD, EF.DG1, EF.DG2 and EF.DG5 to EF.DG16 of the logical MRTD. FDP_ACF.1.3 TheTSF shallexplicitly authorize accessof subjects toobjects basedon the following sensitive rules: none. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.036 Security Target FDP_ACF.1.4 The TSF shall explicitly deny access of subjects to objects based on the rules: 1. Any terminal is not allowed to modify any of the EF.DG1 to EF.DG16 of the logical MRTD 2. Any terminal is not allowed to read any of the EF.DG1 to EF.DG16 of the logical MRTD 3. The Basic Inspection System is not allowed to read the data in EF.DG3 and EF.DG4. Note 32: The inspection system needs special authentication and authorization for read ac- cess to DG3 and DG4 defined in BSI-CC-PP-0056 [CC_PP-0056]. 6.1.4.1 Inter-TSF-Transfer Note 33: FDP_UCT.1 and FDP_UIT.1 require the protection of the User Data transmitted from the TOE to the terminal by secure messaging with encryption and message authentication codes after successful authentication of the terminal. The authentication mechanisms as part of Basic Access Control Mechanism include the key agreement for the encryption and the message authentication key to be used for secure messaging. The TOE shall meet the requirement “Basic data exchange confidentiality (FDP_UCT.1)” as specified below (Common Criteria Part 2 [CC_Part2]). FDP_UCT.1 Basic data exchange confidentiality – MRTD Hierarchical to: No other components. Dependencies: [FTP_ITC.1 Inter-TSF trusted channel or FTP_TRP.1 Trusted path] [FDP_ACC.1 Subset access control or FDP_IFC.1 Subset information flow control] FDP_UCT.1.1 The TSF shall enforce the Basic Access Control SFP to be able to transmit and receive objects in a manner protected from unauthorized disclosure. The TOE shall meet the requirement “Data exchange integrity (FDP_UIT.1)” as specified be- low (Common Criteria Part 2 [CC_Part2]). FDP_UIT.1 Data exchange integrity – MRTD Hierarchical to: No other components. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.037 Security Target Dependencies: [FDP_ACC.1 Subset access control or FDP_IFC.1 Subset information flow control] [FTP_ITC.1 Inter-TSF trusted channel or FTP_TRP.1 Trusted path] FDP_UIT.1.1 The TSF shall enforce the Basic Access Control SFP to be able to transmit and receive user data in a manner protected from modification, deletion, insertion and replay errors FDP_UIT.1.2 The TSF shall be able to determine on receipt of user data, whether modification, deletion, insertion and replay has occurred 6.1.5 Class FMT Security Management Note 34: The SFR FMT_SMF.1 and FMT_SMR.1 provide basic requirements to the manage- ment of the TSF data. The TOE shall meet the requirement “Specification of Management Functions (FMT_SMF.1)” as specified below (Common Criteria Part 2 [CC_Part2]). FMT_SMF.1 Specification of Management Functions Hierarchical to: No other components. Dependencies: No Dependencies FMT_SMF.1.1 The TSF shall be capable of performing the following security manage- ment functions: 1. Initialization 2. Pre-personalization 3. Personalization The TOE shall meet the requirement “Security roles (FMT_SMR.1)” as specified below (Com- mon Criteria Part 2 [CC_Part2]). FMT_SMR.1 Security roles Hierarchical to: No other components. Dependencies: FIA_UID.1 Timing of identification FMT_SMR.1.1 The TSF shall maintain the roles: 1. Manufacturer 2. Personalization Agent 3. Basic Inspection System FMT_SMR.1.2 The TSF shall be able to associate users with roles MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.038 Security Target Note 35: The SFR FMT_LIM.1 and FMT_LIM.2 address the management of the TSF and TSF data to prevent misuse of test features of the TOE over the life cycle phases. The TOE shall meet the requirement “Limited capabilities (FMT_LIM.1” as specified below (Common Criteria Part 2 [CC_Part2] extended). FMT_LIM.1 Limited capabilities Hierarchical to: No other components. Dependencies: FMT_LIM.2 Limited availability. FMT_LIM.1.1 The TSF shall be designed in a manner that limits their capabilities so that in conjunction with “Limited availability (FMT_LIM.2)” the follow- ing policy is enforced: Deploying Test Features after TOE Delivery does not allow 1. User Data to be disclosed or manipulated 2. TSF data to be disclosed or manipulated 3. Software to be reconstructed 4. Substantial information about construction of TSF to be gathered which may enable other attacks The TOE shall meet the requirement “Limited availability (FMT_LIM.2)” as specified below (Common Criteria Part 2 [CC_Part2] extended). FMT_LIM.2 Limited availability Hierarchical to: No other components. Dependencies: FMT_LIM.1 Limited capabilities. FMT_LIM.2.1 The TSF shall be designed in a manner that limits their capabilities so that in conjunction with “Limited capabilities (FMT_LIM.1)” the follow- ing policy is enforced: Deploying Test Features after TOE Delivery does not allow 1. User Data to be disclosed or manipulated 2. TSF data to be disclosed or manipulated 3. Software to be reconstructed 4. Substantial information about construction of TSF to be gathered which may enable other attacks Note 36: The formulation of “Deploying Test Features ...” in FMT_LIM.2.1 might be a little bit misleading since the addressed features are no longer available (e.g. by disabling or remov- MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.039 Security Target ingtherespectivefunctionality). NeverthelessthecombinationofFMT_LIM.1andFMT_LIM.2 is introduced provide an optional approach to enforce the same policy. Note that the term “software” in item 3 of FMT_LIM.1.1and FMT_LIM.2.1 refers to both IC Dedicated and IC Em- bedded Software. The TOE shall meet the requirement “Management of TSF data (FMT_MTD.1)” as specified below (Common Criteria Part 2 [CC_Part2]). The iterations address different management functions and different TSF data. FMT_MTD.1/INI_ENA ManagementofTSFdata–WritingofInitializationDataandPreper- sonalization Data Hierarchical to: No other components. Dependencies: FMT_SMF.1 Specification of management functions FMT_SMR.1 Security roles FMT_MTD.1.1/ INI_ENA The TSF shall restrict the ability to write the Initialization Data and Pre-personalization Data to the Manufacturer Note 37: The Pre-personalization Data include but are not limited to the authentication ref- erence data for the Personalization Agent which is the symmetric cryptographic Personaliza- tion Agent Key. FMT_MTD.1/INI_DIS Management of TSF data – Disabling of Read Access to Initialization Data and Pre-personalization Data Hierarchical to: No other components. Dependencies: FMT_SMF.1 Specification of management functions FMT_SMR.1 Security roles FMT_MTD.1.1/ INI_DIS The TSF shall restrict the ability to disable read access for users to the Initialization Data to the Personalization Agent Note 38: According to P.Manufact the IC Manufacturer and the MRTD Manufacturer are the default users assumed by the TOE in the role Manufacturer during the phase 2 “Manufactur- ing” but the TOE is not requested to distinguish between these users within the role Man- ufacturer. The TOE restricts the ability to write the Initialization Data and the Prepersonal- ization Data by (i) allowing to write these data only once and (ii) blocking the role Manu- facturer at the end of the phase 2. The IC Manufacturer writes the Initialization Data which includes but are not limited to the IC Identifier as required by FAU_SAS.1. The Initialization Data provides a unique identification of the IC which is used to trace the IC in the phase 2 and 3 “personalization” but is not needed and may be misused in the phase 4 “Operational Use”. Therefore the external read access will be blocked. The MRTD Manufacturer will write the Pre-personalization Data. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.040 Security Target FMT_MTD.1/KEY_WRITE Management of TSF data – Key Write Hierarchical to: No other components. Dependencies: FMT_SMF.1 Specification of management functions FMT_SMR.1 Security roles FMT_MTD.1.1/ KEY_WRITE The TSF shall restrict the ability to write the Document Basic Access Keys to the Personalization Agent FMT_MTD.1/KEY_READ Management of TSF data – Key Read Hierarchical to: No other components. Dependencies: FMT_SMF.1 Specification of management functions FMT_SMR.1 Security roles FMT_MTD.1.1/ KEY_READ The TSF shall restrict the ability to read the Document Basic Access Keys and Personalization Agent Keys to none Note 39: The Personalization Agent generates, stores and ensures the correctness of the Document Basic Access keys. 6.1.6 Class FPT Protection of Security Functions The TOE shall prevent inherent and forced illicit information leakage for User Data and TSF data. The security functional requirement FPT_EMSEC.1 addresses the inherent leakage. With respect to the forced leakage they have to be considered in combination with the secu- rity functional requirements “Failure with preservation of secure state (FPT_FLS.1)” and “TSF testing (FPT_TST.1)” on the one hand and “Resistance to physical attack (FPT_PHP.3)” on the other. The SFR “Non-bypassability of the TSP (FPT_RVM.1)” and “TSF domain sepa- ration (FPT_SEP.1)” together with “Limited capabilities (FMT_LIM.1)”, “Limited availability (FMT_LIM.2)” and “Resistance to physical attack (FPT_PHP.3)” prevent bypassing, deactiva- tion and manipulation of the security features or misuse of TOE functions. The TOE shall meet the requirement “TOE Emanation (FPT_EMSEC.1)” as specified below (Common Criteria Part 2 [CC_Part2] extended). FPT_EMSEC.1 TOE Emanation Hierarchical to: No other components. Dependencies: No dependencies. FPT_EMSEC.1.1 The TOE shall not emit information about IC power consumption and command execution time in excess of non-useful information enabling access to Personalization Agent Key(s) and transport keys. FPT_EMSEC.1.2 The TSF shall ensure any unauthorized users are unable to use the following interface smart card circuit contacts to gain access to Personalization Agent Key(s) and transport keys. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 41 Security Target Note 40: The TOE shall prevent attacks against the listed secret data where the attack is based on external observable physical phenomena of the TOE. Such attacks may be observ- able at the interfaces of the TOE or may be originated from internal operation of the TOE or may be caused by an attacker that varies the physical environment under which the TOE operates. The set of measurable physical phenomena is influenced by the technology em- ployed to implement the smart card. The MRTD’s chip has to provide a smart card contact- less interface but may have also (not used by the terminal but maybe by an attacker) sensi- tive contacts according to ISO/IEC 7816-2 as well. Examples of measurable phenomena in- clude, but are not limited to variations in the power consumption, the timing of signals and the electromagnetic radiation due to internal operations or data transmissions. The following security functional requirements address the protection against forced illicit information leakage including physical manipulation. The TOE shall meet the requirement “Failure with preservation of secure state (FPT_FLS.1)” as specified below (Common Criteria Part 2 [CC_Part2]). FPT_FLS.1 Failure with preservation of secure state Hierarchical to: No other components. Dependencies: No dependencies. FPT_FLS.1.1 The TSF shall preserve a secure state when the following types of fail- ures occur: 1. Exposure to out-of-range operating conditions where therefore a malfunction could occur 2. failure detected by TSF according to FPT_TST.1 The TOE shall meet the requirement “TSF testing (FPT_TST.1)” as specified below (Common Criteria Part 2 [CC_Part2]). FPT_TST.1 TSF testing Hierarchical to: No other components. Dependencies: No dependencies. FPT_TST.1.1 The TSF shall run a suite of self tests during initial start-up and at the condition “request of random numbers“ to demonstrate the correct operation of the TSF. FPT_TST.1.2 The TSF shall provide authorized users with the capability to verify the integrity of TSF data. FPT_TST.1.3 The TSF shall provide authorized users with the capability to verify the integrity of stored TSF executable code. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.042 Security Target The TOE shall meet the requirement “Resistance to physicalattack (FPT_PHP.3)” as specified below (Common Criteria Part 2 [CC_Part2]). FPT_PHP.3 Resistance to physical attack Hierarchical to: No other components. Dependencies: No dependencies. FPT_PHP.3.1 The TSF shall resist physical manipulation and physical probing to the TSF by responding automatically such that the SFRs are always en- forced. Note 41: The TOE will implement appropriate measures to continuously counter physical manipulation and physical probing. Due to the nature of these attacks (especially manipu- lation) the TOE can by no means detect attacks on all of its elements. Therefore, permanent protection against these attacks is required ensuring that the TSP could not be violated at any time. Hence, “automatic response” means here (i) assuming that there might be an at- tack at any time and (ii) countermeasures are provided at any time. 6.2 Security Assurance Requirements for the TOE The for the evaluation of the TOE and its development and operating environment are those taken from the Evaluation Assurance Level EAL4 and augmented by taking the following components: • ALC_DVS.2 MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.043 Security Target 6.3 Security Requirements Rationale 6.3.1 Security Functional Requirements Rationale The table 6.2 provides an overview for security functional requirements coverage. OT.AC_Pers OT.Data_Int OT.Data_Conf OT.Identification OT.Prot_Inf_Leak OT.Prot_Phys-Tamper OT.Prot_Malfunction OT.Prot_Abuse-Func FAU_SAS.1 x FCS_CKM.1 x x x FCS_CKM.4 x x FCS_COP.1/SHA x x x FCS_COP.1/ENC x x x FCS_COP.1/AUTH x x FCS_COP.1/MAC x x x FCS_RND.1 x x x FIA_UID.1 x x FIA_AFL.1 x x FIA_UAU.1 x x FIA_UAU.4 x x x FIA_UAU.5 x x x FIA_UAU.6 x x x FDP_ACC.1 x x x FDP_ACF.1 x x x FDP_UCT.1 x x x FDP_UIT.1 x x x FMT_SMF.1 x x x FMT_SMR.1 x x x FMT_LIM.1 x FMT_LIM.2 x FMT_MTD.1/INI_ENA x FMT_MTD.1/INI_DIS x FMT_MTD.1/KEY_WRITE x x x FMT_MTD.1/KEY_READ x x x FPT_EMSEC.1 x x MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.044 Security Target FPT_TST.1 x x FPT_FLS.1 x x x FPT_PHP.3 x x x Table 6.2: Coverage of Security Objectives for the TOE by SFR OT.AC_Pers The security objective OT.AC_Pers “Access Control for Personalization of log- ical MRTD” addresses the access control of the writing the logical MRTD. The write access to the logical MRTD data are defined by the SFR FDP_ACC.1 and FDP_ACF.1 as follows: only the successfully authenticated Personalization Agent is allowed to write the data of the groups EF.DG1 to EF.DG16 of the logical MRTD only once. The authentication of the terminal as Personalization Agent shall be performed by TSF according to SFR FIA_UAU.4 and FIA_UAU.5. The Personalization Agent can be authenticated either by using the BAC mechanism (FCS_CKM.1, FCS_COP.1/SHA, FCS_RND.1 (for key gener- ation), and FCS_COP.1/ENC as well as FCS_COP.1/MAC) with the personalization key or for reasons of interoperability with [CC_PP-0056] by using the symmetric authentication mech- anism (FCS_COP.1/AUTH). In case of using the BAC mechanism the SFR FIA_UAU.6 describes the re-authentication and FDP_UCT.1 and FDP_UIT.1 the protection of the transmitted data by means of se- cure messaging implemented by the cryptographic functions according to FCS_CKM.1, FCS_COP.1/SHA, FCS_RND.1 (for key generation), and FCS_COP.1/ENC as well as FCS_COP.1/MAC for the ENC_MAC_Mode. The SFR FMT_SMR.1 lists the roles (including Personalization Agent) and the SFR FMT_SMF.1 lists the TSF management functions (including Personalization) setting the Doc- ument Basic Access Keys according to the SFR FMT_MTD.1/KEY_WRITE as authentication reference data. The SFR FMT_MTD.1/KEY_READ prevents read access to the secret key of the Personalization Agent Keys and ensure together with the SFR FCS_CKM.4, FPT_EMSEC.1, FPT_FLS.1 and FPT_PHP.3 the confidentially of these keys. OT.Data_Int The security objective OT.Data_Int “Integrity of personal data” requires the TOE to protect the integrity of the logical MRTD stored on the MRTD’s chip against physical manipulation and unauthorized writing. The write access to the logical MRTD data is defined by the SFR FDP_ACC.1 and FDP_ACF.1 in the same way: Only the Personalization Agent is al- lowed to write the data of the groups EF.DG1 to EF.DG16 of the logical MRTD (FDP_ACF.1.2, rule 1) and terminals are not allowed to modify any of the data groups EF.DG1 to EF.DG16 of the logical MRTD (cf. FDP_ACF.1.4). The SFR FMT_SMR.1 lists the roles (including Personaliza- tion Agent) and the SFR FMT_SMF.1 lists the TSF management functions (including Personal- ization). The authentication of the terminal as Personalization Agent shall be performed by TSF according to SFR FIA_UAU.4, FIA_UAU.5 and FIA_UAU.6 using either FCS_COP.1/ENC and FCS_COP.1/MAC or FCS_ COP.1/AUTH. The security objective OT.Data_Int “Integrity of personal data” requires the TOE to en- sure that the inspection system is able to detect any modification of the transmitted logical MRTD data by means of the BAC mechanism. The SFR FIA_UAU.6, FDP_UCT.1 and FDP_UIT.1 MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.045 Security Target require the protection of the transmitted data by means of secure messaging implemented by the cryptographic functions according to FCS_CKM.1, FCS_COP.1/SHA, FCS_RND.1 (for key generation), and FCS_COP.1/ENC and FCS_COP.1/MAC for the ENC_MAC_Mode. The SFR FMT_MTD.1/KEY_WRITE requires the Personalization Agent to establish the Document Ba- sic Access Keys in a way that they cannot be read by anyone in accordance to FMT_MTD.1/ KEY_READ. OT.Data_Conf The security objective OT.Data_Conf “Confidentiality of personal data” re- quires the TOE to ensure the confidentiality of the logical MRTD data groups EF.DG1 to EF.DG16. The SFR FIA_UID.1 and FIA_UAU.1 allow only those actions before identification respective authentication which do not violate OT.Data_Conf. In case of failed authentica- tion attempts FIA_AFL.1 enforces additional waiting time prolonging the necessary amount of time for facilitating a brute force attack. The read access to the logical MRTD data is de- finedbytheFDP_ACC.1andFDP_ACF.1.2: thesuccessfulauthenticatedPersonalizationAgent is allowed to read the data of the logical MRTD (EF.DG1 to EF.DG16). The successful authenti- catedBasicInspectionSystemisallowedtoreadthedataofthelogicalMRTD(EF.DG1, EF.DG2 and EF.DG5 to EF.DG16). The SFR FMT_SMR.1 lists the roles (including Personalization Agent and Basic Inspection System) and the SFR FMT_SMF.1 lists the TSF management functions (including Personalization for the key management for the Document Basic Access Keys). The SFR FIA_UAU.4 prevents reuse of authentication data to strengthen the authen- tication of the user. The SFR FIA_UAU.5 enforces the TOE to accept the authentica- tion attempt as Basic Inspection System only by means of the Basic Access Control Authentication Mechanism with the Document Basic Access Keys. Moreover, the SFR FIA_UAU.6 requests Secure Messaging after successful authentication of the terminal with Basic Access Control Authentication Mechanism which includes the protection of the transmitted data in ENC_MAC_Mode by means of the cryptographic functions accord- ing to FCS_COP.1/ENC and FCS_COP.1/MAC for key generation(cf. the SFR FDP_UCT.1 and FDP_UIT.1), and FCS_COP.1/ENC and FCS_COP.1/ MAC for the ENC_MAC_Mode. The SFR FCS_CKM.1, FCS_CKM.4, FCS_COP.1/SHA and FCS_RND.1 establish the key management for thesecuremessagingkeys. TheSFRFMT_MTD.1/KEY_WRITEaddressesthekeymanagement and FMT_MTD.1/KEY_READ prevents reading of the Document Basic Access Keys. Note, neither the security objective OT.Data_Conf nor the SFR FIA_UAU.5 requires the Personalization Agent to use the Basic Access Control Authentication Mechanism or secure messaging. OT.Identification The security objective OT.Identification “Identification and Authenti- cation of the TOE” address the storage of the IC Identification Data uniquely identifying the MRTD’s chip in its non-volatile memory. This will be ensured by TSF according to SFR FAU_SAS.1. Furthermore, the TOE shall identify itself only to a successful authenticated Basic Inspec- tionSysteminphase4“OperationalUse”. TheSFRFMT_MTD.1/INI_ENAallowsonlytheMan- ufacturer to write Initialization Data and Pre-personalization Data (including the Personal- ization Agent key). The SFR FMT_MTD.1/INI_DIS allows the Personalization Agent to disable Initialization Data if their usage in the phase 4 “Operational Use” violates the security ob- jective OT.Identification. The SFR FIA_UID.1 and FIA_UAU.1 do not allow reading of any data MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.046 Security Target uniquely identifying the MRTD’s chip before successful authentication of the Basic Inspec- tion Terminal and will stop communication after unsuccessful authentication attempt. In case of failed authentication attempts FIA_AFL.1 enforces additional waiting time prolong- ing the necessary amount of time for facilitating a brute force attack. OT.Prot_Abuse-Func The security objective OT.Prot_Abuse-Func “Protection against Abuse of Functionality” is ensured by the SFR FMT_LIM.1 and FMT_LIM.2 which prevent mis- use of test functionality of the TOE or other features which may not be used after TOE Deliv- ery. OT.Prot_Inf_Leak The security objective OT.Prot_Inf_Leak “Protection against Informa- tion Leakage” requires the TOE to protect confidential TSF data stored and/or processed in the MRTD’s chip against disclosure • by measurement and analysis of the shape and amplitude of signals or the time be- tween events found by measuring signals on the electromagnetic field, power con- sumption, clock, or I/O lines which is addressed by the SFRs FPT_EMSEC.1 • by forcing a malfunction of the TOE which is addressed by the SFR FPT_FLS.1 and FPT_TST.1, and/or • by a physical manipulation of the TOE which is addressed by the SFR FPT_PHP.3 OT.Prot_Phys-Tamper The security objective OT.Prot_Phys-Tamper “Protection against Physical Tampering” is covered by the SFR FPT_PHP.3. OT.Prot_Malfunction The security objective OT.Prot_Malfunction “Protection against Malfunctions” is covered by (i) the SFR FPT_TST.1 which requires self tests to demonstrate the correct operation and tests of authorized users to verify the integrity of TSF data and TSF code and (ii) the SFR FPT_FLS.1 which requires a secure state in case of detected failure or operating conditions possibly causing a malfunction. 6.3.2 Dependency Rationale The dependency analysis for the security functional requirements shows that the basis for mutual support and internal consistency between all defined functional requirements is sat- isfied. All dependencies between the chosen functional components are analyzed, and non- dissolved dependencies are appropriately explained. Table 6.3 shows the dependencies between the SFR of the TOE. SFR Dependencies Support of the Depen- dencies FAU_SAS.1 No dependencies n.a. FCS_CKM.1 [FCS_CKM.2 Cryptogr. key distribution or FCS_COP.1 Cryptogr. operation], Fulfilled by FCS_COP.1/ENC, and FCS_COP.1/MAC, MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.047 Security Target SFR Dependencies Support of the Depen- dencies FCS_CKM.4 Cryptogr. key destruction Fulfilled by FCS_CKM.4 FCS_CKM.4 [FDP_ITC.1 Import of user data without secu- rity attributes, FDP_ITC.2 Import of user data with security at- tributes, or FCS_CKM.1 Cryptogr. key generation] Fulfilled by FCS_CKM.1 FCS_COP.1/SHA [FDP_ITC.1 Import of user data without secu- rity attributes, FDP_ITC.2 Import of user data with security at- tributes, or FCS_CKM.1 Cryptogr. key generation], justification 1 for non- satisfied dependencies FCS_CKM.4 Cryptogr. key destruction Fulfilled by FCS_CKM.4 FCS_COP.1/ENC [FDP_ITC.1 Import of user data without secu- rity attributes, FDP_ITC.2 Import of user data with security at- tributes, or FCS_CKM.1 Cryptogr. key generation], Fulfilled by FCS_CKM.1, FCS_CKM.4 Cryptogr. key destruction Fulfilled by FCS_CKM.4 FCS_COP.1/AUTH [FDP_ITC.1 Import of user data without secu- rity attributes, FDP_ITC.2 Import of user data with security at- tributes, or FCS_CKM.1 Cryptogr. key generation], justification 2 for non- satisfied dependencies FCS_CKM.4 Cryptogr. key destruction justification 2 for non- satisfied dependencies FCS_COP.1/MAC [FDP_ITC.1 Import of user data without secu- rity attributes, FDP_ITC.2 Import of user data with security at- tributes, or FCS_CKM.1 Cryptogr. key generation], Fulfilled by FCS_CKM.1, FCS_CKM.4 Cryptogr. key destruction Fulfilled by FCS_CKM.4 FCS_RND.1 No dependencies n.a. FCS_UID.1 No dependencies n.a. FIA_AFL.1 FIA_UAU.1 Timing of authentication Fulfilled by FIA_UAU.1 FIA_UAU.1 FIA_UID.1 Timing of identification Fulfilled by FIA_UID.1 FIA_UAU.4 No dependencies n.a. FIA_UAU.5 No dependencies n.a. FIA_UAU.6 No dependencies n.a. FDP_ACC.1 FDP_ACF.1 Security attribute based access control Fulfilled by FDP_ACF.1 FDP_ACF.1 FDP_ACC.1 Subset access control, Fulfilled by FDP_ACC.1, MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.048 Security Target SFR Dependencies Support of the Depen- dencies FMT_MSA.3 Static attribute initialization justification 3 for non- satisfied dependencies FDP_UCT.1 [FTP_ITC.1 Inter-TSF trusted channel, or FTP_TRP.1 Trusted path], justification 4 for non- satisfied dependencies [FDP_ACC.1 Subset access control, or FDP_IFC.1 Subset information flow control] Fulfilled by FDP_ACC.1 FDP_UIT.1 [FTP_ITC.1 Inter-TSF trusted channel, or FTP_TRP.1 Trusted path], justification 4 for non- satisfied dependencies [FDP_ACC.1 Subset access control, or FDP_IFC.1 Subset information flow control] Fulfilled by FDP_ACC.1 FMT_SMF.1 No dependencies n.a. FMT_SMR.1 FIA_UID.1 Timing of identification Fulfilled by FIA_UID.1 FMT_LIM.1 FMT_LIM.2 Fulfilled by FMT_LIM.2 FMT_LIM.2 FMT_LIM.1 Fulfilled by FMT_LIM.1 FMT_MTD.1/INI_ENA FMT_SMF.1 Specification of management functions, Fulfilled by FMT_SMF.1 FMT_SMR.1 Security roles Fulfilled by FMT_SMR.1 FMT_MTD.1/INI_DIS FMT_SMF.1 Specification of management functions, Fulfilled by FMT_SMF.1 FMT_SMR.1 Security roles Fulfilled by FMT_SMR.1 FMT_MTD.1/ KEY_WRITE FMT_SMF.1 Specification of management functions, Fulfilled by FMT_SMF.1 FMT_SMR.1 Security roles Fulfilled by FMT_SMR.1 FMT_MTD.1/ KEY_READ FMT_SMF.1 Specification of management functions, Fulfilled by FMT_SMF.1 FMT_SMR.1 Security roles Fulfilled by FMT_SMR.1 FPT_EMSEC.1 No dependencies n.a. FPT_FLS.1 No dependencies n.a. FPT_PHP.3 No dependencies n.a. FPT_TST.1 No dependencies n.a. Table 6.3: Dependencies between the SFR for the TOE Justification for non-satisfied dependencies between the SFR for TOE No. 1 The hash algorithm required by the SFR FCS_COP.1/SHA does not need any key material. Therefore neither a key generation (FCS_CKM.1 nor an import (FDP_ITC.1/2) is necessary. No. 2 The SFR FCS_COP.1/AUTH uses the symmetric Personalization Key permanently stored during the Pre-Personalization process (cf. FMT_MTD.1/INI_ENA) by the man- ufacturer. Thus there is neither the necessity to generate or import a key during the MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.049 Security Target addressed TOE life cycle by the means of FCS_CKM.1 or FDP_ITC. Since the key is per- manently stored within the TOE there is no need for FCS_CKM.4, too. No. 3 The access control TSF according to FDP_ACF.1 uses security attributes which are defined during the personalization and are fixed over the whole life time of the TOE. No management of these security attribute (i.e. SFR FMT_MSA.1 and FMT_MSA.3) is necessary here. No. 4 The SFR FDP_UCT.1 and FDP_UIT.1 require the use secure messaging between the MRTD and the BIS respectively GIS. There is no need for the SFR FTP_ITC.1, e.g. to re- quire this communication channel to be logically distinct from other communication channels since there is only one channel. Since the TOE does not provide a direct hu- man interface a trusted path as required by FTP_TRP.1 is not applicable here. 6.3.3 Security Assurance Requirements Rationale The EAL4 was chosen to permit a developer to gain maximum assurance from security en- gineering based upon rigorous commercial development practices supported by moderate application of specialist security engineering techniques. EAL4 is the highest level at which it is likely to be economically feasible to retrofit to an existing product line. EAL4 is appli- cable in those circumstances where developers or users require a moderate to high level of independently assured security in conventional commodity TOEs and are prepared to incur sensitive security specific engineering costs. The selection of the component ALC_DVS.2 provides a higher assurance of the security of the MRTD’s development and manufacturing especially for the secure handling of the MRTD’s material. The component ALC_DVS.2 has no dependencies. All of these are met or exceeded in the EAL4 assurance package. 6.3.4 Security Requirements – Mutual Support and Internal Consis- tency The following part of the security requirements rationale shows that the set of security re- quirements for the TOE consisting of the security functional requirements (SFRs) and the se- curity assurance requirements (SARs) together forms a mutually supportive and internally consistent whole. The analysis of the TOE’s security requirements with regard to their mutual support and internal consistency demonstrates: The dependency analysis in section 6.3.2 Dependency Rationale for the security func- tional requirements shows that the basis for mutual support and internal consistency be- tween all defined functional requirements is satisfied. All dependencies between the cho- sen functional components are analyzed, and non-satisfied dependencies are appropriately explained. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.050 Security Target The assurance class EAL4 is an established set of mutually supportive and internally con- sistent assurance requirements. The dependency analysis for the additional assurance in section 6.3.3 Security Assurance Requirements Rationale components shows that the as- surance requirements are mutually supportive and internally consistent as all (additional) dependencies are satisfied and no inconsistency appears. Inconsistency between functional and assurance requirements could only arise if there are functional-assurance dependencies which are not met, a possibility which has been shown not to arise in sections 6.3.2 Dependency Rationale and 6.3.3 Security Assurance Re- quirements Rationale. Furthermore, as also discussed in section 6.3.3 Security Assurance Requirements Rationale, the chosen assurance components are adequate for the function- ality of the TOE. So the assurance requirements and security functional requirements sup- port each other and there are no inconsistencies between the goals of these two groups of security requirements. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 51 Security Target 7 TOE Summary Specification (ASE_TSS.1) This chapter describes the TOE Security Functions and the Assurance Measures covering the requirements of the previous chapter. 7.1 TOE Security Functions This chapter gives the overview description of the different TOE Security Functions compos- ing the TSF. 7.1.1 TOE Security Functions from Hardware (IC) and Cryptographic Li- brary 7.1.1.1 F.IC_CL: Security Functions of the Hardware (IC) and Cryptographic Library This security function covers the security functions of the hardware and the cryptographic library. The Security Targets of the hardware define the following security functionalities, which are identical in [IFX_ST-SLE78-D11-G12] and [IFX_ST-SLE78-P11]: MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.052 Security Target TSF Used by the TOE Description SF_DPM x Device phase management SF_PS x Protection against snooping SF_PMA x Protection against modification attacks SF_PLA x Protection against logical attacks SF_CS Cryptographic support TDES x Encryption and decryption (hardware implementation) TDES (SCL) – Encryption and decryption (software implementation) AES x Encryption and decryption (hardware implementation) AES (SCL) – Encryption and decryption (software implementation) RSA – Encryption, decryption, signature generation and verification; asymmetric key generation EC – Signature generation and verification; asymmetric key genera- tion; asymmetric key agreement SHA-2 – SHA-2 library for hash value calculation SCL – Symmetric crypto library TRNG x True Random Number Generator SF_MAE – Mutual Authentication Extension Table 7.1: Security functionality provided by the hardware and cryptographic library. 7.1.2 TOESecurityFunctionsfromEmbeddedSoftware(ES)–Operating system 7.1.2.1 F.Access_Control This TSF regulates all access by external entities to operations of the TOE which are only executed after this TSF allowed access. This function consists of following elements: 1. Access to objects is controlled based on subjects, objects (any file) and security at- tributes. 2. No access control policy allows reading of any key. 3. Any access not explicitly allowed is denied. 4. Access control in phase 2 – initialization/pre-personalization – enforces initialization and pre-personalization policy: configuration and initialization of the TOE, configur- ing of Access Control policy and doing key management only by the manufacturer (Initialization/Pre-personalization Agent) or on behalf of him (see F.Management). 5. Access control in phase 3 – personalization – enforces personalization policy: writing of user data, keys (Basic Access Control) and reading of initialization data only by the Personalization Agent identified with its authentication key (see F.Management). MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.053 Security Target 6. Access control in phase 4 – operational use – enforces operational use policy: reading of user data by BIS authenticated at least by Secure Messaging with BAC. 7.1.2.2 F.Identification_Authentication This function provides identification/authentication of the user roles • Manufacturer (Initialization/Pre-personalization Agent), • Personalization Agent and • Basic Inspection System by the methods: 1. Personalization phase: • Symmetric authentication [FIPS_197, NIST_SP800-38B] with following proper- ties: – It uses a challenge from the TOE. – The cryptographic method for confidentiality is AES-128/CBC provided by F.Crypto. – The cryptographic method for authenticity is CMAC provided by F.Crypto. – On error (wrong MAC, wrong challenge) the user role is not identi- fied/authenticated. – After three consecutive failed authentication attempts the authentication method is blocked and the key is no longer usable (retry counter with a value of 3). – A usage counter of 50.000 prevents the unlimited usage of the key. The counter cannot be reset. After the limit is reached, the key is irreversibly blocked. – On success the session keys are created and stored for Secure Messaging. – Keys and data in transient memory are overwritten after usage. • Secure Messaging with following properties: – The cryptographic method for confidentiality is AES-128/CBC provided by F.Crypto. – The cryptographic method for authenticity is CMAC provided by F.Crypto. – In a Secure Messaging protected command the method for confidentiality and the method for authenticity must be present. – The initialization vector is an encrypted Send Sequence Counter (SSC) for encryption and MAC. – A session key is used. – The Secure Messaging session is limited by a Secure Messaging counter of 500.000; the decrease of the counter is depending on the length of the com- mand and response APDUs. If a new Secure Messaging session is started, the counter is reset to 500.000. – Upon any command that is not protected correctly with the session keys theseareoverwrittenaccordingto[FIPS_140-3](orbetter)andanewauthen- tication is required. – Keys and data in transient memory are overwritten after usage. 2. Operational use phase: MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.054 Security Target • Symmetric BAC authentication method [ICAO_9303] with following properties: – The authentication is as specified by ICAO. – It uses a challenge from the MRTD. – The method can be configured by the administrator to delay the processing of the authentication command after a failed authentication. – The cryptographic method for confidentiality is Triple-DES/CBC provided by F.Crypto. – The cryptographic method for authenticity is DES/Retail MAC provided by F.Crypto. – On error (wrong MAC, wrong challenge) the user role is not identi- fied/authenticated. – On success the session keys are created and stored for Secure Messaging. • Secure Messaging with following properties: – The Secure Messaging is as specified by ICAO. – The cryptographic method for confidentiality is Triple-DES/CBC provided by F.Crypto. – The cryptographic method for authenticity is DES/Retail MAC provided by F.Crypto. – In a Secure Messaging protected command the method for confidentiality and the method for authenticity must be present. – The initialization vector is an encrypted Send Sequence Counter (SSC). – In phases 3 and 4 a session key is used. – The Secure Messaging session is limited by a Secure Messaging counter of 500.000; the decrease of the counter is depending on the length of the com- mand and response APDUs. If a new Secure Messaging session is started, the counter is reset to 500.000. – On any command that is not protected correctly with the session keys these are overwritten according to [FIPS_140-3] (or better) and a new BAC authen- tication is required. – Keys in transient memory are overwritten after usage. 7.1.2.3 F.Management In phase 2 the Manufacturer (Initialization/Pre-personalization Agent) performs the initial- ization and configures the file layout including security attributes. In any case the layout de- termines that the parameters given in F.Access_Control for phases 3 and 4 are enforced. The agent can also do key management and other administrative tasks. In phase 3 the Personalization Agent performs following steps: • Formatting of all data to be stored in the TOE according to ICAO requirements which are outside the scope of the TOE. The data to be formatted includes the index file, data groups, PassiveAuthenticationdata, BACkeyderivedfromtheMachineReadableZone data and parameters. • Writing of all the required data to the appropriate files as specified in [ICAO_9303]. • Changing the TOE into the end-usage mode for phase 4 where reading of the initializa- tion data is prevented. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.055 Security Target 7.1.2.4 F.Crypto This function provides the implementation to • DES • Triple-DES/CBC • DES/Retail MAC • AES used in phase 3 • CMAC used in phase 3 This function implements the hash algorithms according to FIPS 180-2 [FIPS_180-4] • SHA-1 This function implements the post-processing of the random number generator • RNG (PTG.3, supplied by F.IC_CL) 7.1.2.5 F.Verification TOE internal functions ensures correct operation. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.056 Security Target 7.2 Assurance Measures The assurance measures fulfilling the requirements of EAL4 augmented with ALC_DVS.2 is given in table 7.2. Measure Measure ADV_ARC.1 Security architecture description ADV_FSP.4 Complete functional specification 4 ADV_IMP.1 Implementation representation of the TSF 4 ADV_TDS.3 Basic modular design AGD_OPE.1 Operational user guidance AGD_PRE.1 Preparative procedures ALC_CMC.4 Production support, acceptance procedures, automation ALC_CMS.4 Problem tracking CM coverage ALC_DEL.1 Delivery procedures ALC_DVS.2 Sufficiency of security measures ALC_LCD.1 Developer defined life-cycle model ALC_TAT.1 Well-defined development tools ATE_COV.2 Analysis of coverage ATE_DPT.1 Testing: basic design ATE_FUN.1 Functional testing ATE_IND.2 Independent testing – sample AVA_VAN.3 Focused vulnerability analysis Table 7.2: Assurance Measures MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.057 Security Target 7.3 TOE Summary Specification Rationale Table 7.3 shows the coverage of the SFRs by TSFs. SFR TSFs FAU_SAS.1 F.IC_CL FCS_CKM.1 F.IC_CL FCS_CKM.4 F.Identification_Authentication FCS_COP.1/SHA F.Crypto FCS_COP.1/ENC F.Crypto FCS_COP.1/AUTH F.Crypto FCS_COP.1/MAC F.Crypto FCS_RND.1 F.IC_CL, F.Crypto FIA_UID.1 F.Access_Control FIA_UAU.1 F.Access_Control FIA_UAU.4 F.Identification_Authentication FIA_UAU.5 F.Access_Control, F.Identification_Authentication FIA_UAU.6 F.Identification_Authentication FIA_AFL.1 F.Access_Control, F.Identification_Authentication FDP_ACC.1 F.Access_Control FDP_ACF.1 F.Access_Control FDP_UCT.1 F.Identification_Authentication FDP_UIT.1 F.Identification_Authentication FMT_SMF.1 F.Management FMT_SMR.1 F.Identification_Authentication FMT_LIM.1 F.IC_CL FMT_LIM.2 F.IC_CL FMT_MTD.1/INI_ENA F.IC_CL, F.Access_Control FMT_MTD.1/INI_DIS F.Access_Control, F.Management FMT_MTD.1/KEY_WRITE F.Access_Control FMT_MTD.1/KEY_READ F.Access_Control FPT_EMSEC.1 F.IC_CL FPT_FLS.1 F.IC_CL FPT_TST.1 F.IC_CL, F.Verification FPT_PHP.3 F.IC_CL Table 7.3: Coverage of SFRs for the TOE by TSFs. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.058 Security Target The SFR FAU_SAS.1 requires the storage of the chip identification data which is ad- dressed in F.IC_CL (SF_DPM). The SFR FCS_CKM.1 requires the BAC key derivation algorithm, which is supplied by the BAC authentication mechanism of F.Identification_Authentication. The SFR FCS_CKM.4 requires the destroying of cryptographic keys. This is done in F.Identification_Authentication (“Overwrites keys in transient memory after usage”). The SFR FCS_COP.1/SHA requires SHA-1. F.Crypto provides this hash algorithm. The SFR FCS_COP.1/ENC requires Triple-DES in CBC mode and cryptographic key size 112 bit to perform Secure Messaging - encryption and decryption. This is provided by F.Crypto. The SFR FCS_COP.1/AUTH requires AES in CBC mode and cryptographic key size 128 bit to perform Secure Messaging - encryption and decryption. This is provided by F.Crypto. The SFR FCS_COP.1/MAC requires Triple-DES in Retail MAC mode and cryptographic key size 112 bit to perform Secure Messaging - Message Authentication Code. This is provided by F.Crypto. The SFR FCS_RND.1 requires the generation of random numbers which is provided by F.IC_CL (SF_CS(TRNG)) and F.Crypto. The provided random number generator produces cryptographically strong random numbers which are used at the appropriate places as writ- ten in the addition there. The SFR FIA_UID.1 requires timing of identification. It is handled by F.Access_Control which enforces identification of a role before access is granted (“...only executed after this TSFallowedaccess”). Alsoallpoliciespreventreadingsensitiveoruserdependentdatawith- out user identification. The SFR FIA_UAU.1 requires timing of authentication. It is handled by F.Access_Control which enforces authentication of a role before access is granted (“...only executed after this TSFallowedaccess”). Alsoallpoliciespreventreadingsensitiveoruserdependentdatawith- out user authentication. TheSFRFIA_UAU.4requirespreventionofauthenticationdatareuse. Thisisinparticular fulfilled by using changing initialization vectors in Secure Messaging. Secure Messaging is provided by F.Identification_Authentication. The SFR FIA_UAU.5 requires Basic Access Control authentication mechanism and sym- metric authentication mechanism based on Triple-DES. In addition SFR FIA_UAU.5 also re- quires the authentication of any user’s claimed identity. F.Identification_Authentication and F.Access_Control fulfill these requirements. The SFR FIA_UAU.6 requires re-authentication for each command after successful au- thentication. This is done by F.Identification_Authentication providing Secure Messaging. The SFR FIA_AFL.1 requires the detection of an unsuccessful authentication attempt and thewaitingforaspecifiedtimebetweenthereceptionofanauthenticationcommandandits processing. F.Identification_Authentication detects unsuccessful authentication attempts and can be used “to delay the processing of the authentication command after a failed au- thentication command”. The SFR FDP_ACC.1 requires the enforcement of the access control policy on terminals gainingwrite, readandmodificationaccesstodataintheEF.COM,EF.SOD,EF.DG1toEF.DG16. This is done by F.Access_Control (based on the objects: “a. data EF.DG1 to EF.DG16 ...”). MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.059 Security Target The SFR FDP_ACF.1 requires the enforcement of the access control policy which is done by F.Access_Control (“Access to objects is controlled based on subjects, objects (any files) and security attributes”). The SFR FDP_UCT.1 requires the transmitting and receiving data protected from unauthorized disclosure after Basic Access Control. This is done by using an en- crypted communication channel, which is based on Secure Messaging provided by F.Identification_Authentication. The SFR FDP_UIT.1 requires the transmitting and receiving data protected from modi- fication, deletion, insertion and replay after Basic Access Control. This is done by using an protected communication channel. This channel is based on Secure Messaging provided by F.Identification_Authentication. A send sequence counter makes each command unique while the authenticity method makes it possible to detect modifications. The SFR FMT_SMF.1 requires security management functions for initialization, per- sonalization and configuration. This is done by F.Management: The Manufacturer (Initialization/Pre-personalization Agent) performs the Initialization and configures the file layout in phase 2, the Personalization Agent performs the personalization in phase 3. The SFR FMT_SMR.1 requires the maintenance of roles. The roles are managed by F.Identification_Authentication. The SFR FMT_LIM.1 requires limited capabilities of test functions which is provided by F.IC_CL (SF_DPM) which controls what commands can be executed thereby preventing ex- ternal usable test functions to do harm. The IC Dedicated Test Software only is available in the test mode. The SFR FMT_LIM.2 requires limited availabilities of test functions which is provided by F.IC_CL (SF_DPM) which controls what commands can be executed thereby preventing ex- ternal usable test functions to do harm and the access to memory and special function reg- isters. The IC Dedicated Test Software only is available in the test mode. The SFR FMT_MTD.1/INI_ENA requires writing of Initialization data and Pre- personalization data to the manufacturer. Writing of Pre-personalization and Installation data only by the manufacturer is enforced by F.Access_Control, which limits these opera- tions to phase 2. In addition F.IC_CL (SF_DPM) stores this data in the User Read Only Area which cannot be changed afterwards. The SFR FMT_MTD.1/INI_DIS requires only the Personalization agent to be able to dis- able reading of the Initialization data. This is provided by F.Management (Personalization agent: “Changing the TOE into the end-usage mode for phase 4 where reading of the Initial- ization data is prevented”) and F.Access_Control. The SFR FMT_MTD.1/KEY_WRITE requires the Personalization agent to be able to write the Document Basic Access Keys. This is provided by F.Access_Control allowing the person- alization agent in phase 3 to write all necessary data. The SFR FMT_MTD.1/KEY_READ requires the Document Basic Access Keys and the Per- sonalization Agent Keys to never be readable. This is enforced by F.Access_Control, which does not allow reading of any key to any role. The SFR FPT_EMSEC.1 requires limiting of emanations. This is provided by F.IC_CL (SF_PS). MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.060 Security Target The SFR FPT_FLS.1 requires failure detection and preservation of a secure state. This is provided by F.IC_CL (SF_PS, SF_PMA, SF_PLA). The security functions audit continually and react to environmental and other problems by bringing the IC into a secure state. The SFR FPT_TST.1 requires testing for (a) correct operation, (b) integrity of data and (c) integrity of executable code. F.Verification does this testing. F.IC_CL (SF_CS, SF_PMA) con- trols all NVM and FLASH content for integrity. The SFR FPT_PHP.3 requires resistance to physical manipulation and probing. This is provided by F.IC_CL (SF_DPM, SF_PS, SF_PMA, SF_PLA) which is provided by the hardware to resist attacks. 7.4 Statement of Compatibility This is a statement of compatibility between this composite Security Target and the Security Targets of SLE78CLFX400VPHM/BPHM/7PHM (M7892) [IFX_ST-SLE78-D11-G12, IFX_ST-SLE78-P11]. 7.4.1 Relevance of Hardware TSFs All security functions of the hardware and cryptographic library that are used by the TOE (as indicated in Table 7.1) are relevant for the composite Security Target. 7.4.2 Compatibility: TOE Security Environment 7.4.2.1 Security Objectives Table 7.4 gives a mapping of the hardware security objectives to those of the composite ST. . HW objective Matches TOE objective Remarks O.Phys-Manipulation (protection against physical manipula- tion) OT.Prot_Phys-Tamper O.Phys-Probing (protection against physical probing) OT.Prot_Phys-Tamper O.Malfunction (protection against malfunctions) OT.Prot_Malfunction O.Leak-Inherent (protection against inherent informa- tion leakage) OT.Prot_Inf_Leak O.Leak-Forced (protection against forced information leakage) OT.Prot_Inf_Leak O.Abuse-Func (protection against abuse of functional- ity) OT.Prot_Abuse-Func MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.061 Security Target HW objective Matches TOE objective Remarks O.Identification (TOE identification) OT.Identification O.RND (random numbers) – no conflict O.Cap_Avail_Loader (capability and availability of the loader) – not applicable (the loader is deactivated before delivery) O.TDES (cryptographic service Triple-DES) OT.Data_Int OT.Data_Conf O.AES (cryptographic service AES) OT.Data_Int OT.Data_Conf O.SHA (cryptographic service hash function) – no conflict O.Authentication (authentication to external entities) – no conflict O.Prot_TSF_Confidentiality (protection of the confidentiality of the TSF) – no conflict O.Ctrl_Auth_Loader/Package1+ (access control and authenticity for the loader) – no conflict O.Add-Functions (additional specific security functional- ity) – no conflict O.Mem-Access (area based memory access control) OT.Prot_Malfunction OT.Prot_Abuse-Func OT.Prot_Phys-Tamper OE.Lim_Block_Loader (limitationofcapabilityandblockingthe loader) – not applicable (the loader is deactivated before delivery) OE.Loader_Usage/Package1+ (secure usage of the Loader) – not applicable (the loader is deactivated before delivery) OE.TOE_Auth (external entities authenticating of the TOE) – no conflict OE.Resp-Appl (treatment of user data) – no conflict OE.Process-Sec-IC (protection during composite product manufacturing) – no conflict Table 7.4: Mapping of hardware to TOE security objectives including those of the environ- ment. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.062 Security Target 7.4.2.2 Security Requirements Table 7.5 addresses the platform security requirements and their relevance for the TOE. Nei- thertheSFRsthatcanbemappedtotheplatformSFRsnorthosethatareapplicationspecific (and thus not listed in the table) show any conflicts with the platform SFRs. HW SFRs Matches TOE SFR Remarks FRU_FLT.2 (limited fault tolerance) FPT_FLS.1 FPT_TST.1 FPT_FLS.1 (failure with preservation of secure state) FPT_FLS.1 FMT_LIM.1 (limited capabilities) FMT_LIM.1 FMT_LIM.2 (limited availability) FMT_LIM.2 FAU_SAS.1 (audit storage) FAU_SAS.1 FDP_SDC.1 (stored data confidentiality) – used implicitly, no conflict FDP_SDI.2 (storeddataintegritymonitoringandac- tion) – used implicitly, no conflict FPT_PHP.3 (resistance to physical attack) FPT_PHP.3 FDP_ITT.1 (basic internal transfer protection) FPT_EMSEC.1 FPT_ITT.1 (basic internal TSF data transfer protec- tion) FPT_EMSEC.1 FDP_IFC.1 (subset information flow control) FPT_EMSEC.1 FCS_RNG.1 (random number generation) FCS_RND.1 FIA_API.1 (authentication proof of identity) – not applicable FMT_LIM.1/Loader (limited capabilities – loader) – not applicable (loader deac- tivated before delivery) FMT_LIM.2/Loader (limited availability – loader) – not applicable (loader deac- tivated before delivery) FCS_COP.1/TDES (cryptographic operation – TDES) FCS_COP.1/ENC FCS_COP.1/MAC FCS_CKM.4/TDES (cryptographic key destruction – TDES) – used implicitly, no conflict MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.063 Security Target HW SFRs Matches TOE SFR Remarks FCS_COP.1/AES (cryptographic operation – AES) FCS_COP.1/AUTH FCS_CKM.4/AES (cryptographic key destruction – AES) – used implicitly (for person- alization), no conflict FCS_COP.1/SHA (cryptographic operation –SHA) – notusedbytheTOE,nocon- flict FPT_TST.2 (subset TOE security testing) FPT_TST.1 FDP_ACC.1 (subset access control) FDP_ACC.1 FDP_ACF.1 (security attribute based access control) FDP_ACF.1 FMT_MSA.1 (management of security attributes) – used implicitly, no conflict FMT_MSA.3 (static attribute initialization) – used implicitly, no conflict FMT_SMF.1 (specification of management func- tions) FMT_SMF.1 FCS_COP.1/RSA-1 (cryptographic operation – RSA (ACL v2.03.008)) – notusedbytheTOE,nocon- flict FCS_COP.1/RSA-2 (cryptographic operation – RSA (ACL v2.07.003)) – notusedbytheTOE,nocon- flict FCS_CKM.1/RSA-1 (cryptographic key management – RSA (ACL v2.03.008)) – notusedbytheTOE,nocon- flict FCS_CKM.1/RSA-2 (cryptographic key management – RSA (ACL v2.07.003)) – notusedbytheTOE,nocon- flict FCS_CKM.4/RSA (cryptographic key destruction – RSA (optional)) – notusedbytheTOE,nocon- flict FCS_COP.1/ECDSA-1 (cryptographic operation – ECDSA (ACL v2.03.008)) – notusedbytheTOE,nocon- flict FCS_COP.1/ECDSA-2 (cryptographic operation – ECDSA (ACL v2.07.003)) – notusedbytheTOE,nocon- flict FCS_CKM.1/EC-1 (cryptographic key generation – ECDSA (ACL v2.03.008)) – notusedbytheTOE,nocon- flict MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.064 Security Target HW SFRs Matches TOE SFR Remarks FCS_CKM.1/EC-2 (cryptographic key generation – ECDSA (ACL v2.07.003)) – notusedbytheTOE,nocon- flict FCS_COP.1/ECDH-1 (cryptographic operation – ECDH (ACL v2.03.008)) – notusedbytheTOE,nocon- flict FCS_COP.1/ECDH-2 (cryptographic operation – ECDH (ACL v2.07.003)) – notusedbytheTOE,nocon- flict FCS_COP.1/TDES_SCL (cryptographic operation – TDES_SCL) – notusedbytheTOE,nocon- flict FCS_CKM.4/TDES_SCL (cryptographic key destruction – TDES_SCL) – notusedbytheTOE,nocon- flict FCS_COP.1/AES_SCL (cryptographic operation – AES_SCL) – notusedbytheTOE,nocon- flict FCS_CKM.4/AES_SCL (cryptographic key destruction – AES_SCL) – notusedbytheTOE,nocon- flict FDP_ACC.1/Loader (subset access control – loader) – not applicable (loader deac- tivated before delivery) FDP_ACF.1/Loader (security attribute based access control – loader) – not applicable (loader deac- tivated before delivery) Table 7.5: Mapping of hardware to TOE SFRs. 7.4.2.3 Assurance Requirements The level of assurance of the • TOE is EAL4 augmented with ALC_DVS.2 • Hardware is EAL6 augmented with ALC_FLR.1 This shows that the assurance requirements of the TOE matches the assurance require- ments of the hardware. 7.4.3 Conclusion Overall no contradictions between the Security Targets of the TOE and the hardware can be found. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.065 Security Target 8 Glossary and Acronyms Active Authentication Security mechanism defined in [ICAO_9303] option by which means the MRTD’s chip proves and the Inspection System verifies the identity and au- thenticity of the MRTD’s chip as part of a genuine MRTD issued by a known State of organization. Application note / Note Optional informative part of the ST containing sensitive sup- porting information that is considered relevant or useful for the construction, evalua- tion, or use of the TOE. Audit records Write-only-oncenon-volatilememoryareaoftheMRTD’schiptostorethe Initialization Data and Pre-personalization Data. Authenticity Ability to confirm the MRTD and its data elements on the MRTD’s chip were created by the issuing State or Organization Basic Access Control (BAC) Security mechanism defined in [ICAO_9303] by which means the MRTD’s chip proves and the Inspection System protects their communica- tion by means of Secure Messaging with Basic Access Keys (see there). Basic Inspection System (BIS) An Inspection System which implements the terminals part of the Basic Access Control Mechanism and authenticates itself to the MRTD’s chip using the Document Basic Access Keys derived form printed MRZ data for reading the logical MRTD. Biographical data (biodata) The personalized details of the MRTD holder of the docu- ment appearing as text in the visual and machine readable zones on the biographical data page of a passport book or on a travel card or visa. [ICAO_9303] Biometric reference data Data stored for biometric authentication of the MRTD holder in the MRTD’s chip as (i) digital portrait and (ii) optional biometric reference data. Counterfeit An unauthorized copy or reproduction of a genuine security document made by whatever means. [ICAO_9303] Country Signing CA Certificate (CCSCA) Self-signed certificate of the Country Signing CA Public Key (KPuCSCA) issued by CSCA stored in the Inspection System. Document Basic Access Keys Pair of symmetric (two-key) Triple-DES keys used for Se- cure Messaging with encryption (key KENC) and message authentication (key KMAC) of data transmitted between the MRTD’s chip and the Inspection System [ICAO_9303]. It is drawn from the printed MRZ of the passport book to authenticate an entity able to read the printed MRZ of the passport book. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.066 Security Target Document Security Object (SOD) A RFC3369 CMS Signed Data Structure, signed by the Document Signer (DS). Carries the hash values of the LDS Data Groups. It is stored in the MRTD’s chip. It may carry the Document Signer Certificate (CDS). [ICAO_9303] Eavesdropper A threat agent with enhanced basic attack potential reading the commu- nication between the MRTD’s chip and the Inspection System to gain the data on the MRTD’s chip. Enrollment The process of collecting biometric samples from a person and the subse- quent preparation and storage of biometric reference templates representing that per- son’s identity. [ICAO_9303] Extended Access Control Security mechanism identified in [ICAO_9303] by which means the MRTD’s chip (i) verifies the authentication of the Inspection Systems au- thorized to read the optional biometric reference data, (ii) controls the access to the optional biometric reference data and (iii) protects the confidentiality and integrity of the optional biometric reference data during their transmission to the Inspection Sys- tem by Secure Messaging. The Personalization Agent may use the same mechanism to authenticate themselves with Personalization Agent Private Key and to get write and read access to the logical MRTD and TSF data. Extended Inspection System (EIS) A role of a terminal as part of an Inspection System which is in addition to Basic Inspection System authorized by the issuing State or Or- ganization to read the optional biometric reference data and supports the terminals part of the Extended Access Control Authentication Mechanism. Forgery Fraudulent alteration of any part of the genuine document, e.g. changes to the biographical data or the portrait. [ICAO_9303] Global Interoperability The capability of Inspection Systems (either manual or auto- mated) in different States throughout the world to exchange data, to process data re- ceived from systems in other States, and to utilize that data in inspection operations in their respective States. Global interoperability is a major objective of the standard- ized specifications for placement of both eye readable and machine readable data in all MRTDs. [ICAO_9303] IC Dedicated Support Software That part of the IC Dedicated Software (refer to above) which provides functions after TOE Delivery. The usage of parts of the IC Dedicated Software might be restricted to certain phases. IC Dedicated Test Software That part of the IC Dedicated Software (refer to above) which is used to test the TOE before TOE Delivery but which does not provide any func- tionality thereafter. IC Identification Data The IC manufacturer writes a unique IC identifier to the chip to control the IC as MRTD material during the IC manufacturing and the delivery process to the MRTD manufacturer. Impostor A person who applies for and obtains a document by assuming a false name and identity, or a person who alters his or her physical appearance to represent him- self or herself as another person for the purpose of using that person’s document. [ICAO_9303] Improperly documented person A person who travels, or attempts to travel with: (a) an expired travel document or an invalid visa; (b) a counterfeit, forged or altered travel MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.067 Security Target document or visa; (c) someone else’s travel document or visa; or (d) no travel docu- ment or visa, if required. [ICAO_9303] Initialization Process of writing Initialization Data (see below) to the TOE (cf. sec. 1.2, TOE life cycle, phase 2, step 3). Initialization Data Any datadefined bythe TOEManufacturer andinjected intothe non- volatile memory by the Integrated Circuits manufacturer (phase 2). These data are for instance used for traceability and for IC identification as MRTD’s material (IC identifi- cation data). Inspection The act of a State examining an MRTD presented to it by a traveler (the MRTD holder) and verifying its authenticity. [ICAO_9303] Inspection system (IS) A technical system used by the border control officer of the re- ceiving State (i) examining an MRTD presented by the traveler and verifying its authen- ticity and (ii) verifying the traveler as MRTD holder. Integrated circuit (IC) Electronic component(s) designed to perform processing and/or memory functions. The MRTD’s chip is an integrated circuit. Integrity Ability to confirm the MRTD and its data elements on the MRTD’s chip have not been altered from that created by the issuing State or Organization. Issuing Organization Organization authorized to issue an official travel document (e.g. the United Nations Organization, issuer of the Laissez-passer). [ICAO_9303] Issuing State The Country issuing the MRTD. [ICAO_9303] Logical Data Structure (LDS) ThecollectionofgroupingsofDataElementsstoredinthe optional capacity expansion technology [ICAO_9303]. The capacity expansion tech- nology used is the MRTD’s chip. Logical MRTD Data of the MRTD holder stored according to the Logical Data Structure [ICAO_9303] as specified by ICAO on the contactless/contact integrated circuit. It presents contactless or contact based readable data including (but not limited to) 1. personal data of the MRTD holder, 2. the digital Machine Readable Zone Data (digital MRZ data, EF.DG1), 3. the digitized portraits (EF.DG2), 4. thebiometricreferencedataoffinger(s)(EF.DG3)oririsimage(s)(EF.DG4)orboth, 5. the other data according to LDS (EF.DG5 to EF.DG16) and 6. EF.COM and EF.SOD. Logical travel document Data stored according to the Logical Data Structure as speci- fied by ICAO in the contactless/contact integrated circuit including (but not limited to) 1. data contained in the machine-readable zone (mandatory), 2. digitized photographic image (mandatory) and 3. fingerprint image(s) and/or iris image(s) (optional). Machine readable travel document (MRTD) Official document issued by a State or Or- ganization which is used by the holder for international travel (e.g. passport, visa, of- ficial document of identity) and which contains mandatory visual (eye readable) data and a separate mandatory data summary, intended for global use, reflecting essential data elements capable of being machine read. [ICAO_9303] MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.068 Security Target Machine readable visa (MRV) A visa or, where appropriate, an entry clearance (here- inafter collectively referred to as visas) conforming to the specifications contained herein, formulated to improve facilitation and enhance security for the visa holder. Contains mandatory visual (eye readable) data and a separate mandatory data sum- mary capable of being machine read. The MRV is normally a label which is attached to a visa page in a passport. [ICAO_9303] Machine readable zone (MRZ) Fixed dimensional area located on the front of the MRTD or MRP Data Page or, in the case of the TD1, the back of the MRTD, containing manda- tory and optional data for machine reading using OCR methods. [ICAO_9303] Machine-verifiable biometrics feature A unique physical personal identification fea- ture (e.g. an iris pattern, fingerprint or facial characteristics) stored on a travel docu- ment in a form that can be read and verified by machine. [ICAO_9303] MRTD application Non-executable data defining the functionality of the operating sys- tem on the IC as the MRTD’s chip. It includes • the file structure implementing the LDS [ICAO_9303], • the definition of the User Data, but does not include the User Data itself (i.e. con- tent of EF.DG1 to EF.DG14, EF.DG16, EF.COM and EF.SOD) and • the TSF Data including the definition the authentication data but except the au- thentication data itself. MRTD Basic Access Control Mutual authentication protocol followed by Secure Mes- saging between the Inspection System and the MRTD’s chip based on MRZ information as key seed and access condition to data stored on MRTD’s chip according to LDS. MRTD holder TherightfulholderoftheMRTDforwhomtheissuingStateorOrganization personalized the MRTD. MRTD’s Chip A contactless or contact based integrated circuit chip complying with ISO/IEC 14443 [ISO_14443] and programmed according to the Logical Data Structure as specified by ICAO, [ICAO_Session12] p. 14. MRTD’s chip Embedded Software Software embedded in a MRTD’s chip and not being developed by the IC Designer. The MRTD’s chip Embedded Software is designed in phase 1 and embedded into the MRTD’s chip in phase 2 of the TOE life cycle. Optional biometric reference data Data stored for biometric authentication of the MRTD holder in the MRTD’s chip as (i) encoded finger image(s) (EF.DG3) or (ii) encoded iris image(s) (EF.DG4) or (iii) both. Note, that the European commission decided to use only fingerprint and not to use iris images as optional biometric reference data. Passive authentication (i) Verification of the digital signature of the Document Security Object and (ii) comparing the hash values of the read LDS data fields with the hash values contained in the Document Security Object. Personalization The process by which the portrait, signature and biographical data are applied to the document. This may also include the optional biometric data collected during the “Enrollment” (cf. sec. 1.2, TOE life cycle, phase 3, step 6). Personalization Agent The agent acting on the behalf of the issuing State or Organiza- tion to personalize the MRTD for the holder by (i) establishing the identity the holder for the biographic data in the MRTD, (ii) enrolling the biometric reference data of the MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.069 Security Target MRTD holder i.e. the portrait, the encoded finger image(s) or (ii) the encoded iris im- age(s) and (iii) writing these data on the physical and logical MRTD for the holder. Personalization Agent Authentication Information TSF data used for authentication proof and verification of the Personalization Agent. Personalization Agent Key Symmetric cryptographic key used (i) by the Personaliza- tion Agent to prove their identity and get access to the logical MRTD and (ii) by the MRTD’schiptoverifytheauthenticationattemptofaterminalasPersonalizationAgent according to the SFR FIA_UAU.4, FIA_UAU.5 and FIA_UAU.6. Physical travel document Travel document in form of paper, plastic and chip using se- cure printing to present data including (but not limited to) 1. biographical data, 2. data of the machine-readable zone, 3. photographic image and 4. other data Pre-personalization Process of writing Pre-Personalization Data (see below) to the TOE including the creation of the MRTD Application (cf. sec. 1.2, TOE life cycle, phase 2, step 5). Pre-personalization Data Any data that is injected into the non-volatile memory of the TOE by the MRTD Manufacturer (phase 2) for traceability of non-personalized MRTD’s and/or to secure shipment within or between life cycle phases 2 and 3. It contains (but is not limited to) the Active Authentication Key Pair and the Personalization Agent Key Pair. Pre-personalized MRTD’s chip MRTD’s chip equipped with a unique identifier and a unique asymmetric Active Authentication Key Pair of the chip. Primary Inspection System (PIS) An inspection system that contains a terminal for the contactless or contact based communication with the MRTD’s chip and does not im- plement the terminals part of the Basic Access Control Mechanism. Random Identifier Random identifier used to establish a communication to the TOE in phase 3 and 4 preventing the unique identification of the MRTD and thus participates in the prevention of traceability. Receiving State The Country to which the Traveler is applying for entry. [ICAO_9303] Reference data Data enrolled for a known identity and used by the verifier to check the verification data provided by an entity to prove this identity in an authentication at- tempt. Secondary image A repeat image of the holder’s portrait reproduced elsewhere in the document by whatever means. [ICAO_9303] Secure Messaging in Encrypted Mode Secure messaging using encryption and mes- sage authentication code according to ISO/IEC 7816-4 [ISO_7816-4]. Skimming Imitation of the Inspection System to read the logical MRTD or parts of it via the contactless or contact based communication channel of the TOE without knowl- edge of the printed MRZ data. Travel document A passport or other official document of identity issued by a State or organization which may be used by the rightful holder for international travel. [ICAO_9303] MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.070 Security Target Traveler Person presenting the MRTD to the Inspection System and claiming the iden- tity of the MRTD holder. TSF data Data created by and for the TOE that might affect the operation of the TOE (CC part 1 [CC_Part1]). Unpersonalized MRTD The MRTD that contains the MRTD Chip holding only Initializa- tion Data and Pre-personalization Data as delivered to the Personalization Agent from the Manufacturer. User data Data created by and for the user that does not affect the operation of the TSF (CC part 1 [CC_Part1]). Verification The process of comparing a submitted biometric sample against the bio- metric reference template of a single enrollee whose identity is being claimed, to de- termine whether it matches the enrollee’s template. [ICAO_9303] Verification data Data provided by an entity in an authentication attempt to prove their identity to the verifier. The verifier checks whether the verification data match the ref- erence data known for the claimed identity. Acronyms Acronym Term BIS Basic Inspection System CC Common Criteria EF Elementary File GIS General Inspection System ICCSN Integrated Circuit Card Serial Number MF Master File n.a. Not applicable OSP Organizational security policy PT Personalization Terminal SAR Security assurance requirements SFR Security functional requirement TOE Target of Evaluation TSF TOE security functions MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.0 71 Security Target Bibliography [AGD] User Guidance MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892), MaskTech Interna- tional GmbH, Version 1.0, 2021-04-09. [BSI_AIS31] Anwendungshinweise und Interpretationen zum Schema – Funk- tionalitätsklassen und Evaluationsmethodologie für physikalische Zufallszahlengeneratoren, BSI, AIS 31, Version 3, 2013-05-15. [BSI_TR-02102-1] BSI TR-02102-1, Kryptographische Verfahren: Empfehlungen und Schlüssellängen, BSI, Version 2020-01, 2020-03-24. [BSI_TR-03110] TR-03110, Advanced Security Mechanisms for Machine Readable Travel Documents, BSI, Version 2.20, 2015. [BSI_TR-03110-1] TR-03110-1, Technical Guideline TR-03110-1: Advanced Security MechanismsforMachineReadableTravelDocumentsandeIDASTo- ken–Part1–eMRTDswithBAC/PACEv2andEACv1, BSI,Version2.20, 2015-02-26. [BSI_TR-03110-3] TR-03110-3, Technical Guideline 03110: Advanced Security Mecha- nisms for Machine Readable Travel Documents and eIDAS Token - Part 3 – Common Specifications, BSI, Version 2.21, 2016-12-21. [BSI_TR-03116-2] TR-03116-2, Technische Richtlinie – Kryptographische Verfahren für Projekte der Bundesregierung - Teil 2 – Hoheitliche Ausweisdoku- mente, BSI, Stand 2020, 2020-01-27. [CC_Part1] CCMB-2017-04-001, Version 3.1, Revision 5, Common Criteria for In- formation Technology Security Evaluation, Part 1: Introduction and General Model, Common Criteria Maintenance Board, 2017-04. [CC_Part2] CCMB-2017-04-002, Version 3.1, Revision 5, Common Criteria for In- formation Technology Security Evaluation, Part 2: Security Func- tional Components, Common Criteria Maintenance Board, 2017-04. [CC_Part3] CCMB-2017-04-003, Version 3.1, Revision 5, Common Criteria for In- formation Technology Security Evaluation, Part 3: Security Assur- ance Components, Common Criteria Maintenance Board, 2017-04. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.072 Security Target [CC_PartEM] CCMB-2017-04-004, Version 3.1, Revision 5, Common Methodol- ogy for Information Technology Security Evaluation, Evaluation Methodology, CommonCriteriaMaintenanceBoard, Version3.1, Re- vision 5, 2017-04. [CC_PP-0055] BSI-CC-PP-0055-2009, Common Criteria Protection Profile / Ma- chine Readable Travel Document with ’ICAO Application’, Basic Ac- cess Control, BSI, Version 1.10, 2009-03-25. [CC_PP-0056] BSI-CC-PP-0056-2009, Common Criteria Protection Profile / Ma- chine Readable Travel Document with ’ICAO Application’, Extended Access Control, BSI, Version 1.10, 2009-03-25. [CC_PP-0084] BSI-CC-PP-0084-2014, Security IC Platform Protection Profile with Augmentation Packages, EUROSMART, Version 1.0, 2014-01-13. [FIPS_140-3] FIPS PUB 140-3, Security Requirements for Cryprographic Modules, National Institute of Standards and Technology, 2019-03. [FIPS_180-4] FIPS PUB 180-4, Secure Hash Standard (SHS), National Institute of Standards and Technology, 2015-08. [FIPS_197] FIPS PUB 197, Specification for the Advanced Encryption Standard (AES), National Institute of Standards and Technology, 2001-11. [ICAO_9303] ICAO Doc 9303, Machine Readable Travel Documents, ICAO, 2015. [ICAO_Session12] Facilitation (FAL) Division, twelfth session, Cairo, ICAO, 10-2004. [IFX_ST-SLE78-D11-G12] BSI-DSZ-CC-0891-V4-2019, Infineon Technologies AG, Security Tar- get Lite ’M7892 Design Steps D11 and G12’, Version 2.1, 2019-11-25. [IFX_ST-SLE78-P11] BSI-DSZ-CC-1105-2020, Infineon Technologies AG, Security Target Lite ’M7892 Design Step P11’, Version 2.2, 2020-04-23. [ISO_10116] ISO/IEC 10116-2017, Information technology – Security techniques - Modes of operation for an n-bit block cipher, ISO/IEC, 2017-07. [ISO_14443] ISO/IEC 14443, Identification cards – Contactless integrated cir- cuit(s) cards – Proximity cards – Multipart Standard, ISO/IEC, 2016- 2018. [ISO_18013-3] ISO/IEC 18013-3:2017, Information technology – Personal identifica- tion–ISO-compliantdrivinglicense–Part3: Accesscontrol,authen- tication and integrity validation, ISO/IEC, 2017-04. [ISO_7816] ISO/IEC 7816, Identification cards – Integrated circuit cards – Multi- part Standard, ISO/IEC, 2008. [ISO_7816-4] ISO/IEC 7816-4:2013, Identification cards – Integrated circuit cards – Part 4: Organization, security and commands for interchange, ISO/IEC, 2013-04. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.073 Security Target [ISO_9797-1] ISO/IEC 9797-1:2011, Information technology – Security techniques – Message Authentication Codes (MACs) – Part 1: Mechanisms using a block cipher, ISO/IEC, 2011. [KiSch-RNG] Version 2.0, A proposal for: Functionality classes for random num- ber generators, W. Killmann and W. Schindler, 2011-09-18. [MT_Manual] MTCOS Pro 2.5 V2 on IFX SLE78C(L)FX40xxPH(M) – Manual, Mask- Tech GmbH, 2021-03-24. Version 1.0. [NIST_SP800-38B] NIST SP 800-38B, Recommendation for Block Cipher Modes of Operation: The CMAC Mode for Authentication, National Institute of Standards and Technology, 2005-05. [NIST_SP800-67] NIST SP 800-67 Rev. 2, Recommendation for the Triple Data Encryp- tion Algorithm (TDEA) Block Cipher, NIST, 2017-11. [NIST_SP800-90A] NIST SP 800-90A Rev. 1, Recommendation for Random Num- ber Generation Using Deterministic Random Bit Generators, Na- tional Institute of Standards and Technology, 2015-06. [SC_HID_MY] BSI-DSZ-CC-S-0156-2020, HID Global GmbH, Site Security Target Lite for HID Global Malaysia, Rev. D, 2020-04-17. [SC_Linxens] BSI-DSZ-CC-S-0143-2019, Linxens (Thailand) Co Ltd., Site Security Target LITE for AY1, Version 2.3, 2019-11-25. MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.074 Security Target 9 Revision History Version Date Author Changes 1.0 2021-04-09 Gudrun Schürer Public version based on v0.5 of the confidential ST MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.075 Security Target 10 Contact MASKTECH GMBH – Headquarters Nordostpark 45 Phone +49 911 955149 0 D-90411 Nuernberg Fax +49 911 955149 7 Germany Email info@masktech.de MASKTECH GMBH – Support Bahnhofstr. 13 Phone +49 911 955149 0 D-87435 Kempten Fax +49 831 5121077 5 Germany Email support@masktech.de MASKTECH GMBH – Sales Lauenburger Str. 15 Phone +49 4151 8990858 D-21493 Schwarzenbek Fax +49 4151 8995462 Germany Email stimm@masktech.de MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.076 Security Target A Overview Cryptographic Algorithms The following cryptographic algorithms are used by the TOE to enforce its security policy: Purpose Cryptographic Mechanism Standard of Implementation Key Size in Bits Standard of Application Comments ST-Reference 1 Authenticated Key Agree- ment / Authentication BAC, Symmetric Authen- tication, based on 3DES in CBC mode [BSI_TR-03110-1] [ICAO_9303] [NIST_SP800-67] (3DES) [ISO_10116] sec. 7 (CBC) also cf. lines 3, 4 112 [BSI_TR-03110-1] [ICAO_9303] FIA_AFL.1 FIA_UAU.4 FIA_UAU.6 2 Authenticated Key Agree- ment / Authentication BAC, Symmetric Authen- tication, based on AES in CBC mode, conforming to BAP standard (basic access protection, driv- ing license). [FIPS_197] (AES) [ISO_10116] sec. 7 (CBC) [ISO_18013-3] Annex B [ICAO_9303] also cf. lines 3, 4 128 [ISO_18013-3] Annex B [ICAO_9303] FCS_COP.1/AUTH 3 Key Derivation BAC Key Derivation, SHA-1 [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] [FIPS_180-4] sec. 6 - [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] FCS_COP.1/SHA 4 Key Derivation Document Basic Ac- cess Key Derivation Algorithm [BSI_TR-03110-1] [ICAO_9303] - [BSI_TR-03110-1] [ICAO_9303] FCS_CKM.1 5 Confidentiality 3DES in CBC mode for Secure Messaging [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] [NIST_SP800-67] (3DES) [ISO_10116] sec. 7 (CBC) 112 [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] FCS_COP.1/ENC FDP_UCT.1 6 Integrity 3DES in Retail MAC mode for Secure Messaging [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] [NIST_SP800-67] (3DES) [ISO_9797-1] sec. 7.4, MAC Algorithm 3 (Retail- MAC) 112 [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] FCS_COP.1/MAC FDP_UIT.1 7 Trusted Channel ICAO BAC Secure Mes- saging in ENC/MAC mode [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] sec. 4 also cf. lines 3, 5, 6 - [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] FCS_COP.1/SHA FCS_COP.1.1/ENC FCS_COP.1/MAC FDP_UIT.1 FDP_UCT.1 8 Cryptographic Primitive PTG.3 Random num- ber generator (PTG.2 and cryptographic post-processing) [BSI_AIS31] [NIST_SP800-90A] sec. 10.2, 10.3.2 - [BSI_TR-03116-2] FCS_RND.1 9 Cryptographic Primitive SHA-1 [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] [FIPS_180-4] sec. 6 - [BSI_TR-03110-1] [BSI_TR-03110-3] [ICAO_9303] FCS_COP.1/SHA Table A.1: Overview Cryptographic Algorithms MTCOS Pro 2.5 V2 EAC with PACE / SLE78CLFX400VPHM/BPHM/7PHM (M7892) (BAC), Version 1.077