Countermeasures represent security concepts and classes of technologies that can be used to prevent a technique or sub-technique from being successfully executed. The below table view not only describes the countermeasure, it also provides informative references to the NIST Risk Management Framework (RMF) revision 5 control identifier. Each NIST control ID is a hyperlink to more information on the control itself. This mapping is meant to be informative and provide traceability to common standards that are being leveraged within the space community. In addition to the table view, there is a Defense-in-Depth (DiD) view that provides the countermeasures overlaid onto Aerospace's DiD model for space systems which was discussed in TOR 2021-01333 REV A. When selecting a specific countermeasure the following information will be displayed: description of the countermeasure, the best segment for countermeasure deployment, any informative references as well as any techniques that the countermeasure addresses. The mapping to countermeasure to technique(s) are a one to many relationship. For the best segment for countermeasure deployment, this is meant to articulate the ideal place to deploy the countermeasure leveraging the following choices: space segment, the development environment, or the ground segment. The space segment is considered to be the spacecraft or spacecrafts if within a constellation. The development segment captures the factories, hardware foundries, the software development organization as well as the Assembly, Test and Launch Operations (ATLO) facilities. The ground segment is meant to capture the operational and maintenance areas for the ground system. This includes the mission operations environments, the antenna environments, the back haul networks, as well as any management network segments for vendors or commercial entities.
Please view the blog post A Look into SPARTA Countermeasures to learn more about SPARTA’s approach to countermeasures and its goal to ensure space system engineers are informed on security principles to mitigate adversary TTPs.
ID | Name | Description | NIST Rev5 Controls | D3FEND | ISO 27001 | |
CM0000 | Countermeasure Not Identified | This technique is a result of utilizing TTPs to create an impact and the applicable countermeasures are associated with the TTPs leveraged to achieve the impact | ||||
CM0001 | Protect Sensitive Information | Organizations should look to identify and properly classify mission sensitive design/operations information (e.g., fault management approach) and apply access control accordingly. Any location (ground system, contractor networks, etc.) storing design information needs to ensure design info is protected from exposure, exfiltration, etc. Space system sensitive information may be classified as Controlled Unclassified Information (CUI) or Company Proprietary. Space system sensitive information can typically include a wide range of candidate material: the functional and performance specifications, any ICDs (like radio frequency, ground-to-space, etc.), command and telemetry databases, scripts, simulation and rehearsal results/reports, descriptions of uplink protection including any disabling/bypass features, failure/anomaly resolution, and any other sensitive information related to architecture, software, and flight/ground /mission operations. This could all need protection at the appropriate level (e.g., unclassified, CUI, proprietary, classified, etc.) to mitigate levels of cyber intrusions that may be conducted against the project’s networks. Stand-alone systems and/or separate database encryption may be needed with controlled access and on-going Configuration Management to ensure changes in command procedures and critical database areas are tracked, controlled, and fully tested to avoid loss of science or the entire mission. Sensitive documentation should only be accessed by personnel with defined roles and a need to know. Well established access controls (roles, encryption at rest and transit, etc.) and data loss prevention (DLP) technology are key countermeasures. The DLP should be configured for the specific data types in question. | AC-3(11) AC-4(23) AC-4(25) CM-12 CM-12(1) PM-11 PM-17 SA-3(1) SA-3(2) SA-4(12) SA-5 SA-9(7) SI-21 SI-23 SR-12 SR-7 | A.8.4 A.8.11 A.8.10 A.8.33 7.5.1 7.5.2 7.5.3 A.5.37 A.8.10 A.5.22 | ||
CM0008 | Security Testing Results | As penetration testing and vulnerability scanning is a best practice, protecting the results from these tests and scans is equally important. These reports and results typically outline detailed vulnerabilities and how to exploit them. As with countermeasure CM0001, protecting sensitive information from disclosure to threat actors is imperative. | AC-3(11) CA-8 RA-5 RA-5(11) SA-11(5) SA-5 | A.8.4 A.8.8 7.5.1 7.5.2 7.5.3 A.5.37 | ||
CM0009 | Threat Intelligence Program | A threat intelligence program helps an organization generate their own threat intelligence information and track trends to inform defensive priorities and mitigate risk. Leverage all-source intelligence services or commercial satellite imagery to identify and track adversary infrastructure development/acquisition. Countermeasures for this attack fall outside the scope of the mission in the majority of cases. | PM-16 PM-16(1) PM-16(1) RA-10 RA-3(2) RA-3(3) SR-8 | A.5.7 A.5.7 A.5.7 | ||
CM0020 | Threat modeling | Use threat modeling and vulnerability analysis to inform the current development process using analysis from similar systems, components, or services where applicable. | SA-11(2) SA-15(8) | |||
CM0022 | Criticality Analysis | Conduct a criticality analysis to identify mission critical functions, critical components, and data flows and reduce the vulnerability of such functions and components through secure system design. Focus supply chain protection on the most critical components/functions. Leverage other countermeasures like segmentation and least privilege to protect the critical components. | CP-2(8) PM-11 PM-17 PM-30 PM-30(1) PM-32 RA-3(1) RA-9 RA-9 SA-15(3) SC-32(1) SC-7(29) SR-1 SR-1 SR-2 SR-2(1) SR-3 SR-3(2) SR-3(3) SR-5(1) SR-7 | A.5.30 4.4 6.2 7.5.1 7.5.2 7.5.3 10.2 A.5.22 5.2 5.3 7.5.1 7.5.2 7.5.3 A.5.1 A.5.2 A.5.4 A.5.19 A.5.31 A.5.36 A.5.37 A.5.19 A.5.20 A.5.21 A.8.30 A.5.20 A.5.21 A.5.22 | ||
CM0024 | Anti-counterfeit Hardware | Develop and implement anti-counterfeit policy and procedures designed to detect and prevent counterfeit components from entering the information system, including tamper resistance and protection against the introduction of malicious code or hardware. | AC-20(5) CM-7(9) PM-30 PM-30(1) RA-3(1) SR-1 SR-10 SR-11 SR-11 SR-11(3) SR-11(3) SR-2 SR-2(1) SR-3 SR-4 SR-4(1) SR-4(2) SR-4(3) SR-4(4) SR-5 SR-5(2) SR-6(1) SR-9 SR-9(1) | 4.4 6.2 7.5.1 7.5.2 7.5.3 10.2 5.2 5.3 7.5.1 7.5.2 7.5.3 A.5.1 A.5.2 A.5.4 A.5.19 A.5.31 A.5.36 A.5.37 A.5.19 A.5.20 A.5.21 A.8.30 A.5.20 A.5.21 A.5.21 A.8.30 A.5.20 A.5.21 A.5.23 A.8.29 | ||
CM0025 | Supplier Review | Conduct a supplier review prior to entering into a contractual agreement with a contractor (or sub-contractor) to acquire systems, system components, or system services. | PM-30 PM-30(1) RA-3(1) SR-11 SR-3(1) SR-3(3) SR-4 SR-4(1) SR-4(2) SR-4(3) SR-4(4) SR-5 SR-5(1) SR-5(2) SR-6 SR-6 | 4.4 6.2 7.5.1 7.5.2 7.5.3 10.2 A.5.21 A.8.30 A.5.20 A.5.21 A.5.23 A.8.29 A.5.22 | ||
CM0026 | Original Component Manufacturer | Components that cannot be procured from the original component manufacturer or their authorized franchised distribution network should be approved by the supply chain board or equivalent to prevent and detect counterfeit and fraudulent parts and materials. | AC-20(5) PM-30 PM-30(1) RA-3(1) SR-1 SR-1 SR-11 SR-2 SR-2(1) SR-3 SR-3(1) SR-3(3) SR-4 SR-4(1) SR-4(2) SR-4(3) SR-4(4) SR-5 SR-5 SR-5(1) SR-5(2) | 4.4 6.2 7.5.1 7.5.2 7.5.3 10.2 5.2 5.3 7.5.1 7.5.2 7.5.3 A.5.1 A.5.2 A.5.4 A.5.19 A.5.31 A.5.36 A.5.37 A.5.19 A.5.20 A.5.21 A.8.30 A.5.20 A.5.21 A.5.21 A.8.30 A.5.20 A.5.21 A.5.23 A.8.29 | ||
CM0027 | ASIC/FPGA Manufacturing | Application-Specific Integrated Circuit (ASIC) / Field Programmable Gate Arrays should be developed by accredited trusted foundries to limit potential hardware-based trojan injections. | PM-30 PM-30(1) RA-3(1) SR-1 SR-1 SR-11 SR-2 SR-2(1) SR-3 SR-5 SR-5(2) SR-6(1) | 4.4 6.2 7.5.1 7.5.2 7.5.3 10.2 5.2 5.3 7.5.1 7.5.2 7.5.3 A.5.1 A.5.2 A.5.4 A.5.19 A.5.31 A.5.36 A.5.37 A.5.19 A.5.20 A.5.21 A.8.30 A.5.20 A.5.21 A.5.20 A.5.21 A.5.23 A.8.29 | ||
CM0028 | Tamper Protection | Perform physical inspection of hardware to look for potential tampering. Leverage tamper proof protection where possible when shipping/receiving equipment. | CA-8(3) CM-7(9) MA-7 PM-30 PM-30(1) RA-3(1) SC-51 SR-1 SR-1 SR-10 SR-11 SR-11(3) SR-2 SR-2(1) SR-3 SR-4(3) SR-4(4) SR-5 SR-5 SR-5(2) SR-6(1) SR-9 SR-9(1) | 4.4 6.2 7.5.1 7.5.2 7.5.3 10.2 5.2 5.3 7.5.1 7.5.2 7.5.3 A.5.1 A.5.2 A.5.4 A.5.19 A.5.31 A.5.36 A.5.37 A.5.19 A.5.20 A.5.21 A.8.30 A.5.20 A.5.21 A.5.20 A.5.21 A.5.23 A.8.29 | ||
CM0041 | User Training | Train users to be aware of access or manipulation attempts by a threat actor to reduce the risk of successful spear phishing, social engineering, and other techniques that involve user interaction. Ensure that role-based security-related training is provided to personnel with assigned security roles and responsibilities: (i) before authorizing access to the information system or performing assigned duties; (ii) when required by information system changes; and (iii) at least annually if not otherwise defined. | AT-2 AT-2(1) AT-2(4) AT-2(4) AT-2(5) AT-2(6) AT-3 AT-3(3) IR-2(3) SR-11(1) | 7.3 A.6.3 A.8.7 A.6.3 | ||
CM0052 | Insider Threat Protection | Establish policy and procedures to prevent individuals (i.e., insiders) from masquerading as individuals with valid access to areas where commanding of the spacecraft is possible. Establish an Insider Threat Program to aid in the prevention of people with authorized access performing malicious activities. | AC-3(11) AC-3(13) AC-3(15) AC-6 AT-2 AT-2(2) AT-2(4) AT-2(5) AT-2(6) AU-10 AU-12 AU-13 AU-6 AU-7 CA-7 IA-12 IA-12(1) IA-12(2) IA-12(3) IA-12(4) IA-12(5) IA-12(6) IA-4 IR-2(3) IR-4 IR-4(6) IR-4(7) MA-7 MP-7 PE-2 PM-12 PM-14 PS-3 PS-4 PS-5 PS-8 RA-10 SC-38 SC-7 SI-4 SR-11(2) | A.8.4 A.5.15 A.8.2 A.8.18 7.3 A.6.3 A.8.7 A.5.25 A.6.8 A.8.15 A.8.15 A.8.12 A.8.16 9.1 9.3.2 9.3.3 A.5.36 A.5.16 A.5.25 A.5.26 A.5.27 A.5.10 A.7.10 A.7.2 A.6.1 A.5.11 A.6.5 A.5.11 A.6.5 7.3 A.6.4 A.5.7 A.5.14 A.8.16 A.8.20 A.8.22 A.8.23 A.8.26 A.8.16 | ||
CM0054 | Two-Person Rule | Utilize a two-person system to achieve a high level of security for systems with command level access to the spacecraft. Under this rule all access and actions require the presence of two authorized people at all times. | AC-3(13) AC-3(15) AC-3(2) IA-12 IA-12(1) IA-12(2) IA-12(3) IA-12(4) IA-12(5) IA-12(6) PE-3 | A.7.1 A.7.2 A.7.3 A.7.4 | ||
CM0002 | COMSEC | Utilizing secure communication protocols with strong cryptographic mechanisms to prevent unauthorized disclosure of, and detect changes to, information during transmission. Systems should also maintain the confidentiality and integrity of information during preparation for transmission and during reception. Spacecraft should not employ a mode of operations where cryptography on the TT&C link can be disabled (i.e., crypto-bypass mode). The cryptographic mechanisms should identify and reject wireless transmissions that are deliberate attempts to achieve imitative or manipulative communications deception based on signal parameters. | AC-17(1) AC-17(10) AC-17(10) AC-17(2) AC-18(1) AC-2(11) AC-3(10) IA-4(9) IA-5 IA-5(7) IA-7 SA-8(18) SA-9(6) SC-10 SC-12 SC-12(1) SC-12(2) SC-12(3) SC-12(6) SC-13 SC-16(3) SC-28(1) SC-28(3) SC-7 SC-7(11) SC-7(18) SI-10 SI-10(3) SI-10(5) SI-10(6) SI-19(4) | A.8.16 A.5.16 A.5.17 A.5.14 A.8.16 A.8.20 A.8.22 A.8.23 A.8.26 A.8.20 A.8.24 A.8.24 A.8.26 A.5.31 A.5.33 A.8.11 | ||
CM0030 | Crypto Key Management | Leverage best practices for crypto key management as defined by organization like NIST or the National Security Agency. Leverage only approved cryptographic algorithms, cryptographic key generation algorithms or key distribution techniques, authentication techniques, or evaluation criteria. Encryption key handling should be performed outside of the onboard software and protected using cryptography. Encryption keys should be restricted so that they cannot be read via any telecommands. | SA-9(6) SC-12 SC-12(1) SC-12(2) SC-12(3) SC-12(6) SC-28(3) | A.8.24 | ||
CM0031 | Authentication | Authenticate all communication sessions (crosslink and ground stations) for all commands before establishing remote connections using bidirectional authentication that is cryptographically based. Adding authentication on the spacecraft bus and communications on-board the spacecraft is also recommended. | AC-17(10) AC-17(10) AC-17(2) AC-18(1) IA-3(1) IA-4 IA-4(9) IA-7 SA-8(15) SA-8(9) SC-16(2) SC-32(1) SC-7(11) SI-14(3) | A.5.16 | ||
CM0033 | Relay Protection | Implement relay and replay-resistant authentication mechanisms for establishing a remote connection or connections on the spacecraft bus. | AC-17(10) AC-17(10) IA-2(8) IA-3 IA-3(1) IA-4 IA-7 SC-13 SC-23 SC-7 SC-7(11) SC-7(18) SI-10 SI-10(5) SI-10(6) | A.5.16 A.5.14 A.8.16 A.8.20 A.8.22 A.8.23 A.8.26 A.8.24 A.8.26 A.5.31 | ||
CM0003 | TEMPEST | The spacecraft should protect system components, associated data communications, and communication buses in accordance with TEMPEST controls to prevent side channel / proximity attacks. Encompass the spacecraft critical components with a casing/shielding so as to prevent access to the individual critical components. | PE-19 PE-19(1) PE-21 | A.7.5 A.7.8 A.8.12 | ||
CM0040 | Shared Resource Leakage | Prevent unauthorized and unintended information transfer via shared system resources. Ensure that processes reusing a shared system resource (e.g., registers, main memory, secondary storage) do not have access to information (including encrypted representations of information) previously stored in that resource during a prior use by a process after formal release of that resource back to the system or reuse | AC-4(23) AC-4(25) SC-2(2) SC-32(1) SC-4 SC-49 SC-50 SC-7(29) | A.8.11 A.8.10 | ||
CM0049 | Machine Learning Data Integrity | When AI/ML is being used for mission critical operations, the integrity of the training data set is imperative. Data poisoning against the training data set can have detrimental effects on the functionality of the AI/ML. Fixing poisoned models is very difficult so model developers need to focus on countermeasures that could either block attack attempts or detect malicious inputs before the training cycle occurs. Regression testing over time, validity checking on data sets, manual analysis, as well as using statistical analysis to find potential injects can help detect anomalies. | AC-3(11) SC-28 SC-28(1) SC-8 SC-8(2) SI-7 SI-7(1) SI-7(2) SI-7(5) SI-7(6) SI-7(8) | A.8.4 A.5.10 A.5.14 A.8.20 A.8.26 A.5.10 A.5.33 | ||
CM0050 | On-board Message Encryption | In addition to authentication on-board the spacecraft bus, encryption is also recommended to protect the confidentiality of the data traversing the bus. | AC-4 AC-4(23) AC-4(24) AC-4(26) AC-4(31) AC-4(32) SA-8(18) SA-8(9) SA-9(6) SC-13 SC-16(2) SC-16(3) SI-19(4) SI-4(10) SI-4(25) | A.5.14 A.8.22 A.8.23 A.8.11 A.8.24 A.8.26 A.5.31 A.8.11 | ||
CM0004 | Development Environment Security | In order to secure the development environment, the first step is understanding all the devices and people who interact with it. Maintain an accurate inventory of all people and assets that touch the development environment. Ensure strong multi-factor authentication is used across the development environment, especially for code repositories, as threat actors may attempt to sneak malicious code into software that's being built without being detected. Use zero-trust access controls to the code repositories where possible. For example, ensure the main branches in repositories are protected from injecting malicious code. A secure development environment requires change management, privilege management, auditing and in-depth monitoring across the environment. | AC-20(5) AC-3(11) AC-3(13) AC-3(15) CA-8 CM-14 CM-2(2) CM-3(2) CM-3(7) CM-3(8) CM-4(1) CM-7(8) CM-7(8) CP-2(8) MA-7 PL-8(2) PM-30 PM-30(1) RA-3(1) RA-3(2) RA-5 RA-5(2) RA-9 SA-10 SA-11 SA-11(1) SA-11(2) SA-11(2) SA-11(4) SA-11(5) SA-11(5) SA-11(6) SA-11(7) SA-11(7) SA-11(8) SA-15 SA-15(3) SA-15(5) SA-15(7) SA-15(8) SA-3 SA-3(1) SA-3(2) SA-4(3) SA-4(5) SC-38 SI-2 SI-2(6) SR-1 SR-1 SR-11 SR-2 SR-2(1) SR-3 SR-3(2) SR-4 SR-4(1) SR-4(2) SR-4(3) SR-4(4) SR-5 SR-5 SR-5(2) SR-6 SR-6(1) SR-6(1) SR-7 | A.8.4 A.8.9 A.8.9 A.8.31 A.5.30 4.4 6.2 7.5.1 7.5.2 7.5.3 10.2 A.8.8 A.5.22 A.5.2 A.5.8 A.8.25 A.8.31 A.8.33 A.8.28 A.8.9 A.8.28 A.8.30 A.8.32 A.8.29 A.8.30 A.8.28 A.5.8 A.8.25 A.8.28 A.6.8 A.8.8 A.8.32 5.2 5.3 7.5.1 7.5.2 7.5.3 A.5.1 A.5.2 A.5.4 A.5.19 A.5.31 A.5.36 A.5.37 A.5.19 A.5.20 A.5.21 A.8.30 A.5.20 A.5.21 A.5.21 A.8.30 A.5.20 A.5.21 A.5.23 A.8.29 A.5.22 A.5.22 | ||
CM0007 | Software Version Numbers | When using COTS or Open-Source, protect the version numbers being used as these numbers can be cross referenced against public repos to identify Common Vulnerability Exposures (CVEs) and exploits available. | AC-3(11) SA-5 | A.8.4 7.5.1 7.5.2 7.5.3 A.5.37 | ||
CM0010 | Update Software | Perform regular software updates to mitigate exploitation risk. Software updates may need to be scheduled around operational down times. Release updated versions of the software/firmware systems incorporating security-relevant updates, after suitable regression testing, at a frequency no greater than mission-defined frequency [i.e., 90 days]. | CM-3(2) CM-3(7) CM-3(8) CM-4(1) SI-2 | A.8.9 A.8.9 A.8.31 A.6.8 A.8.8 A.8.32 | ||
CM0011 | Vulnerability Scanning | Vulnerability scanning is used to identify known software vulnerabilities (excluding custom-developed software - ex: COTS and Open-Source). Utilize scanning tools to identify vulnerabilities in dependencies and outdated software (i.e., software composition analysis). Ensure that vulnerability scanning tools and techniques are employed that facilitate interoperability among tools and automate parts of the vulnerability management process by using standards for: (1) Enumerating platforms, custom software flaws, and improper configurations; (2) Formatting checklists and test procedures; and (3) Measuring vulnerability impact. | CM-10(1) RA-5 RA-5(11) SA-15(7) | A.8.8 | ||
CM0012 | Software Bill of Materials | Generate Software Bill of Materials (SBOM) against the entire software supply chain and cross correlate with known vulnerabilities (e.g., Common Vulnerabilities and Exposures) to mitigate known vulnerabilities. Protect the SBOM according to countermeasures in CM0001. | CM-10(1) CM-11(3) CM-8 CM-8(7) RA-5(11) | A.5.9 A.8.9 | ||
CM0013 | Dependency Confusion | Ensure proper protections are in place for ensuring dependency confusion is mitigated like ensuring that internal dependencies be pulled from private repositories vice public repositories, ensuring that your CI/CD/development environment is secure as defined in CM0004 and validate dependency integrity by ensuring checksums match official packages. | CM-10(1) RA-5 SA-8(9) | A.8.8 | ||
CM0015 | Software Source Control | Prohibit the use of binary or machine-executable code from sources with limited or no warranty and without the provision of source code. | CM-14 CM-7(8) | |||
CM0016 | CWE List | Create prioritized list of software weakness classes (e.g., Common Weakness Enumerations), based on system-specific considerations, to be used during static code analysis for prioritization of static analysis results. | RA-5 SA-11(1) SA-15(7) | A.8.8 A.8.28 | ||
CM0017 | Coding Standard | Define acceptable coding standards to be used by the software developer. The mission should have automated means to evaluate adherence to coding standards. | SA-15 | A.5.8 A.8.25 | ||
CM0018 | Dynamic Analysis | Employ dynamic analysis (e.g., using simulation, penetration testing, fuzzing, etc.) to identify software/firmware weaknesses and vulnerabilities in developed and incorporated code (open source, commercial, or third-party developed code). Testing should occur (1) on potential system elements before acceptance; (2) as a realistic simulation of known adversary tactics, techniques, procedures (TTPs), and tools; and (3) throughout the lifecycle on physical and logical systems, elements, and processes. | CA-8 CP-4(5) RA-5(11) SA-11(5) SA-11(8) SA-11(9) SC-2(2) SC-7(29) SR-6(1) SR-6(1) | |||
CM0019 | Static Analysis | Perform static source code analysis for all available source code looking for system-relevant weaknesses (see CM0016) using no less than two static code analysis tools. | RA-5 SA-11(1) SA-15(7) | A.8.8 A.8.28 | ||
CM0021 | Software Digital Signature | Prevent the installation of Flight Software without verification that the component has been digitally signed using a certificate that is recognized and approved by the mission. | CM-11(3) CM-14 CM-14 SA-10(1) SI-7 SI-7(12) | |||
CM0023 | Configuration Management | Use automated mechanisms to maintain and validate baseline configuration to ensure the spacecraft's is up-to-date, complete, accurate, and readily available. | CM-11(3) CM-3(7) CM-3(8) MA-7 SA-10 SA-10(7) SR-11(2) | A.8.9 A.8.9 A.8.9 A.8.28 A.8.30 A.8.32 | ||
CM0036 | Session Termination | Terminate the connection associated with a communications session at the end of the session or after an acceptable amount of inactivity which is established via the concept of operations. | AC-12 SC-10 SI-14(3) | A.8.20 | ||
CM0039 | Least Privilege | Employ the principle of least privilege, allowing only authorized processes which are necessary to accomplish assigned tasks in accordance with system functions. Ideally maintain a separate execution domain for each executing process. | AC-3(13) AC-3(15) AC-4(2) AC-6 CA-3(6) CM-7 CM-7(8) SA-17(7) SA-8(14) SA-8(15) SA-8(9) SC-2(2) SC-32(1) SC-49 SC-50 SC-7(29) | A.5.15 A.8.2 A.8.18 A.8.19 | ||
CM0046 | Long Duration Testing | Perform testing using hardware or simulation/emulation where the test executes over a long period of time (30+ days). This testing will attempt to flesh out race conditions or time-based attacks. | ||||
CM0047 | Operating System Security | Ensure spacecraft's operating system is scrutinized/whitelisted and has received adequate software assurance previously. The operating system should be analyzed for its attack surface and non-utilized features should be stripped from the operating system. Many real-time operating systems contain features that are not necessary for spacecraft operations and only increase the attack surface. | CM-11(3) CM-7 CM-7(5) CM-7(8) CM-7(8) | A.8.19 A.8.19 | ||
CM0055 | Secure Command Mode(s) | Provide additional protection modes for commanding the spacecraft. These can be where the spacecraft will restrict command lock based on geographic location of ground stations, special operational modes within the flight software, or even temporal controls where the spacecraft will only accept commands during certain times. | AC-17(1) AC-17(10) AC-2(11) AC-2(12) AC-3 AC-3(2) AC-3(3) AC-3(4) AC-3(8) CA-3(7) SC-7 | A.8.16 A.5.15 A.5.33 A.8.3 A.8.4 A.8.18 A.8.20 A.8.2 A.8.16 A.5.14 A.8.16 A.8.20 A.8.22 A.8.23 A.8.26 | ||
CM0062 | Dummy Process - Aggregator Node | According to Securing Sensor Nodes Against Side Channel Attacks, it is practically inefficient to prevent adversaries from identifying aggregator nodes in a network (i.e., constellation) because camouflaging traffic in sensor networks is power intensive. Consequently, focus on preventing adversaries from identifying valid aggregation cycles of aggregator nodes. One solution to counter such attacks is to have each aggregator node execute dummy operations that resemble the average power consumption curve observed during the normal operation of the aggregator node. Apart from simulating the power consumption of a genuine process execution, the two necessities that the execution of the dummy process must incorporate to be successful in thwarting the accumulation phase are to use a different dummy execution process each time or have a low repetition rate. This should help prevent the attacker from finding a pattern that would differentiate the execution of a dummy process from the normal execution of an aggregator node. The second requirement relates to the timing of the execution of the dummy process. Depending on whether there is a pattern to the timing of the execution of a dummy process, a threat actor may be able to identify and disregard the dummy process. For example, if a threat actor is capable of identifying the presence or absence of a radio frequency transmission, the attacker can disregard any power consumption curve computed during the absence of transmission signal. Similarly, if the dummy process is not executed every time the aggregator node receives a transmission, the attacker will be able to identify invalid transmission. Hence, to ensure the effectiveness of this scheme, the dummy process must be executed each time the aggregator receives a transmission as well as randomly during idle periods. The advantage of incorporating dummy processes in an aggregator is to minimize the ease of identifying transmission flow in a sensor network that can be used to identify the base station of the sensor network, which could be highly confidential in critical applications. | PE-19 PE-19(1) | A.7.5 A.7.8 A.8.12 | ||
CM0069 | Process White Listing | Simple process ID whitelisting on the firmware level could impede attackers from instigating unnecessary processes which could impact the spacecraft | CM-7(5) SI-10(5) | A.8.19 | ||
CM0005 | Ground-based Countermeasures | This countermeasure is focused on the protection of terrestrial assets like ground networks and development environments/contractor networks, etc. Traditional detection technologies and capabilities would be applicable here. Utilizing resources from NIST CSF to properly secure these environments using identify, protect, detect, recover, and respond is likely warranted. Additionally, NISTIR 8401 may provide resources as well since it was developed to focus on ground-based security for space systems (https://nvlpubs.nist.gov/nistpubs/ir/2022/NIST.IR.8401.ipd.pdf). Furthermore, the MITRE ATT&CK framework provides IT focused TTPs and their mitigations https://attack.mitre.org/mitigations/enterprise/. Several recommended NIST 800-53 Rev5 controls are provided for reference when designing ground systems/networks. | AC-1 AC-10 AC-11 AC-11(1) AC-12 AC-12(1) AC-14 AC-16 AC-16(6) AC-17 AC-17(1) AC-17(10) AC-17(2) AC-17(3) AC-17(4) AC-17(6) AC-17(9) AC-18 AC-18(1) AC-18(3) AC-18(4) AC-18(5) AC-19 AC-19(5) AC-2 AC-2(1) AC-2(11) AC-2(12) AC-2(13) AC-2(2) AC-2(3) AC-2(4) AC-2(9) AC-20 AC-20(1) AC-20(2) AC-20(3) AC-20(5) AC-21 AC-22 AC-3 AC-3(11) AC-3(13) AC-3(15) AC-3(4) AC-4 AC-4(23) AC-4(24) AC-4(25) AC-4(26) AC-4(31) AC-4(32) AC-6 AC-6(1) AC-6(10) AC-6(2) AC-6(3) AC-6(5) AC-6(8) AC-6(9) AC-7 AC-8 AT-2(4) AT-2(4) AT-2(5) AT-2(6) AT-3 AT-3(2) AT-4 AU-10 AU-11 AU-12 AU-12(1) AU-12(3) AU-14 AU-14(1) AU-14(3) AU-2 AU-3 AU-3(1) AU-4 AU-4(1) AU-5 AU-5(1) AU-5(2) AU-5(5) AU-6 AU-6(1) AU-6(3) AU-6(4) AU-6(5) AU-6(6) AU-7 AU-7(1) AU-8 AU-9 AU-9(2) AU-9(3) AU-9(4) CA-3 CA-3(6) CA-3(7) CA-7 CA-7(1) CA-7(6) CA-8 CA-9 CM-10(1) CM-11 CM-11(2) CM-11(3) CM-12 CM-12(1) CM-14 CM-2 CM-2(2) CM-2(3) CM-2(7) CM-3 CM-3(1) CM-3(2) CM-3(5) CM-3(7) CM-3(7) CM-3(8) CM-4 CM-5(1) CM-5(5) CM-6 CM-6(1) CM-6(2) CM-7 CM-7(1) CM-7(2) CM-7(3) CM-7(5) CM-7(8) CM-7(8) CM-7(9) CM-8 CM-8(1) CM-8(2) CM-8(3) CM-8(4) CM-9 CP-10 CP-10(2) CP-10(4) CP-2 CP-2(2) CP-2(5) CP-2(8) CP-3(1) CP-4(5) CP-8 CP-8(1) CP-8(2) CP-8(3) CP-8(4) CP-8(5) CP-9 CP-9(1) CP-9(2) CP-9(3) IA-11 IA-12 IA-12(1) IA-12(2) IA-12(3) IA-12(4) IA-12(5) IA-12(6) IA-2 IA-2(1) IA-2(12) IA-2(2) IA-2(5) IA-2(6) IA-2(8) IA-3 IA-3(1) IA-4 IA-4(9) IA-5 IA-5(1) IA-5(13) IA-5(14) IA-5(2) IA-5(7) IA-5(8) IA-6 IA-7 IA-8 IR-2 IR-2(2) IR-2(3) IR-3(3) IR-4 IR-4(1) IR-4(11) IR-4(11) IR-4(12) IR-4(13) IR-4(14) IR-4(3) IR-4(4) IR-4(6) IR-4(7) IR-4(8) IR-5 IR-5(1) IR-6 IR-6(1) IR-7 IR-7(1) MA-2 MA-3 MA-3(1) MA-3(2) MA-3(3) MA-4 MA-4(1) MA-4(3) MA-4(6) MA-4(7) MA-5(1) MA-6 MA-7 MP-2 MP-3 MP-4 MP-5 MP-5(4) MP-6 MP-6(3) MP-7 PE-3(7) PL-10 PL-11 PL-8 PL-8(1) PL-8(2) PL-9 PL-9 PM-11 PM-16(1) PM-17 PM-30 PM-30(1) PM-31 PM-32 RA-10 RA-3(1) RA-3(2) RA-3(2) RA-3(3) RA-3(4) RA-5 RA-5(10) RA-5(11) RA-5(2) RA-5(4) RA-5(5) RA-7 RA-9 RA-9 SA-10 SA-10(1) SA-10(7) SA-11 SA-11(2) SA-11(9) SA-15 SA-15(3) SA-15(7) SA-17 SA-2 SA-22 SA-3 SA-3(1) SA-3(2) SA-3(2) SA-4 SA-4(1) SA-4(10) SA-4(12) SA-4(2) SA-4(3) SA-4(5) SA-4(7) SA-4(9) SA-5 SA-8 SA-8(14) SA-8(15) SA-8(18) SA-8(21) SA-8(22) SA-8(23) SA-8(24) SA-8(9) SA-9 SA-9(1) SA-9(2) SA-9(6) SA-9(7) SC-10 SC-12 SC-12(1) SC-12(6) SC-13 SC-15 SC-16(2) SC-16(3) SC-18(1) SC-18(2) SC-18(3) SC-18(4) SC-2 SC-2(2) SC-20 SC-21 SC-22 SC-23 SC-23(1) SC-23(3) SC-23(5) SC-24 SC-28 SC-28(1) SC-28(11) SC-28(3) SC-3 SC-38 SC-39 SC-4 SC-45 SC-45(1) SC-45(1) SC-45(2) SC-49 SC-5 SC-5(1) SC-5(2) SC-5(3) SC-50 SC-51 SC-7 SC-7(10) SC-7(11) SC-7(12) SC-7(13) SC-7(14) SC-7(18) SC-7(21) SC-7(25) SC-7(29) SC-7(3) SC-7(4) SC-7(5) SC-7(5) SC-7(7) SC-7(8) SC-7(9) SC-8 SC-8(1) SC-8(2) SC-8(5) SI-10 SI-10(3) SI-10(6) SI-11 SI-14(3) SI-16 SI-19(4) SI-2 SI-2(2) SI-2(3) SI-2(6) SI-21 SI-3 SI-3 SI-3(10) SI-4 SI-4(1) SI-4(10) SI-4(11) SI-4(12) SI-4(14) SI-4(15) SI-4(16) SI-4(2) SI-4(20) SI-4(22) SI-4(23) SI-4(25) SI-4(4) SI-4(5) SI-5 SI-5(1) SI-6 SI-7 SI-7(1) SI-7(17) SI-7(2) SI-7(5) SI-7(7) SI-7(8) SR-1 SR-1 SR-10 SR-11 SR-11 SR-11(1) SR-11(2) SR-11(3) SR-12 SR-2 SR-2(1) SR-3 SR-3(1) SR-3(2) SR-3(2) SR-3(3) SR-4 SR-4(1) SR-4(2) SR-4(3) SR-4(4) SR-5 SR-5 SR-5(1) SR-5(2) SR-6 SR-6(1) SR-6(1) SR-7 SR-7 SR-8 SR-9 SR-9(1) | 5.2 5.3 7.5.1 7.5.2 7.5.3 A.5.1 A.5.2 A.5.4 A.5.15 A.5.31 A.5.36 A.5.37 A.5.16 A.5.18 A.8.2 A.8.16 A.5.15 A.5.33 A.8.3 A.8.4 A.8.18 A.8.20 A.8.2 A.8.4 A.5.14 A.8.22 A.8.23 A.8.11 A.8.10 A.5.15 A.8.2 A.8.18 A.8.5 A.8.5 A.7.7 A.8.1 A.5.14 A.6.7 A.8.1 A.8.16 A.5.14 A.8.1 A.8.20 A.5.14 A.7.9 A.8.1 A.5.14 A.7.9 A.8.20 A.6.3 A.8.15 A.8.15 A.8.6 A.5.25 A.6.8 A.8.15 A.7.4 A.8.17 A.5.33 A.8.15 A.5.28 A.8.15 A.8.15 A.8.15 A.5.14 A.8.21 9.1 9.3.2 9.3.3 A.5.36 9.2.2 A.8.9 A.8.9 8.1 9.3.3 A.8.9 A.8.32 A.8.9 A.8.9 A.8.9 A.8.9 A.8.19 A.8.19 A.5.9 A.8.9 A.5.2 A.8.9 A.8.19 7.5.1 7.5.2 7.5.3 A.5.2 A.5.29 A.8.1 A.8.6 A.5.30 A.5.29 A.7.11 A.5.29 A.5.33 A.8.13 A.5.29 A.5.16 A.5.16 A.5.16 A.5.17 A.8.5 A.5.16 A.6.3 A.5.25 A.5.26 A.5.27 A.8.16 A.5.5 A.6.8 A.7.10 A.7.13 A.8.10 A.8.10 A.8.16 A.8.10 A.7.13 A.5.10 A.7.7 A.7.10 A.5.13 A.5.10 A.7.7 A.7.10 A.8.10 A.5.10 A.7.9 A.7.10 A.5.10 A.7.10 A.7.14 A.8.10 A.5.10 A.7.10 A.5.8 A.5.7 4.4 6.2 7.5.1 7.5.2 7.5.3 10.2 4.4 6.2 7.4 7.5.1 7.5.2 7.5.3 9.1 9.2.2 10.1 10.2 A.8.8 6.1.3 8.3 10.2 A.5.22 A.5.7 A.5.2 A.5.8 A.8.25 A.8.31 A.8.33 8.1 A.5.8 A.5.20 A.5.23 A.8.29 A.8.30 A.8.28 7.5.1 7.5.2 7.5.3 A.5.37 A.8.27 A.8.28 A.5.2 A.5.4 A.5.8 A.5.14 A.5.22 A.5.23 A.8.21 A.8.9 A.8.28 A.8.30 A.8.32 A.8.29 A.8.30 A.5.8 A.8.25 A.8.25 A.8.27 A.8.6 A.5.14 A.8.16 A.8.20 A.8.22 A.8.23 A.8.26 A.8.23 A.8.12 A.5.10 A.5.14 A.8.20 A.8.26 A.5.33 A.8.20 A.8.24 A.8.24 A.8.26 A.5.31 A.5.14 A.5.10 A.5.33 A.6.8 A.8.8 A.8.32 A.8.7 A.8.16 A.8.16 A.8.16 A.5.6 A.8.11 A.8.10 5.2 5.3 7.5.1 7.5.2 7.5.3 A.5.1 A.5.2 A.5.4 A.5.19 A.5.31 A.5.36 A.5.37 |