Cyber and Physical Security Vulnerability Assessment for IoT-Based Smart Homes
Abstract
:1. Introduction
2. Related Work
3. Risk Assessment Approach
3.1. Establish Drivers Phase
3.2. Profile Assets Phase
3.3. Identify Threats Phase
3.4. Risk Mitigation Phase
4. Results
Risks and Mitigation Approaches in Action
5. Discussion
6. Conclusions
Author Contributions
Conflicts of Interest
References
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Asset ID | Information Asset | Possible Security Threats |
---|---|---|
1 | User credentials | User impersonation |
Identity and credential theft | ||
2 | Mobile personal data and apps | Malicious code injected into apps installed on a phone |
3 | Information modification | |
Information collected by devices | Denial-of-service (DoS) attacks | |
Device or sensor compromising | ||
Smart home status information | Information disclosure | |
Function interruption | ||
4 | Smart home structure | Gain access to inventory information to search for a specific device with known vulnerabilities to attack smart homes |
Inventory information | ||
5 | Log information | Gain access to log data and obtain useful information enabling possible attacks on a smart home system |
6 | Information transmitted via a gateway | Steal information from packets transmitted via a gateway |
7 | Smart home setup information | Information modification |
8 | Video feed of surveillance cameras | Control cameras to monitor and spy on users |
9 | Location tracking information | Observation of location data traffic |
10 | Information resources (e.g., pictures, documents, and music) | Steal private information |
Make stored media inaccessible due to hardware failure |
Threat ID | Possible Impacts (Risks) | Risk Scores |
---|---|---|
Unauthorized access to the main smart home system | ||
1 | Unauthorized execution of operations | 41 |
Loss of control over smart home system | ||
Adversary can take photos, record conversations, and track locations | ||
2 | Attacker can control the smart phone remotely | 41 |
Attacker can make calls and access the phone microphone and camera | ||
Sensor measurements are manipulated to infiltrate the home system | ||
3 | Non-presence tracking leads to home break-in | 39 |
Financial losses | ||
Attacker identifies the weakest device with known vulnerabilities | ||
4 | Attacker takes control of smart home systems | 39 |
Financial losses | ||
Attacker finds a way to access the main system | ||
5 | Attacker changes the system configuration and adding back doors | 39 |
Financial losses | ||
System resources are exhausted via constant self-replication | ||
6 | Possibility of bringing the system down, making it ultimately unusable | 39 |
Possibility of injecting new security vulnerabilities into the system | ||
Difficulty in setting up the smart home system correctly | ||
7 | Misuse of SH systems with the possibility of malfunction | 36 |
Financial losses | ||
User privacy violation | ||
8 | 34 | |
Financial losses | ||
User privacy violation | ||
9 | Breaking into the smart home if it is vacant | 34 |
Financial losses | ||
User privacy violation | ||
10 | Loss of information | 23 |
Damage to reputation |
Asset ID | Real-World Examples |
---|---|
1 | An unauthorized individual obtains the necessary credentials and is able to login into the main smart home system. |
2 | The legitimate user loses his or her mobile device or it becomes stolen, and then the smart home-related apps are manipulated. The phone application can be manipulated remotely via injecting a malicious code. |
3 | An information asset is altered intentionally by malicious individuals to cause the power supply smart meter to show high electricity consumption. |
Jamming and tampering at the physical layer could prevent sensors from detecting risks such as fire, flood, and unexpected motion. | |
A compromised motion sensor could be used to determine when there are people at home. | |
The statuses of door locks and alarm systems could be used to determine when a smart home is occupied. | |
4 | Attackers can gain access to this information asset by obtaining unencrypted backup media or via a social engineering attack. |
5 | This asset can be obtained if the log data are easily accessible via an insecure channel. |
6 | This asset can be obtained if the gateway is not properly secured, e.g., an open Wi-Fi network. The adversary can hijack the Wi-Fi connection, can inject a malicious code, and then takes control over the smart home system. |
7 | This asset can be obtained if the information asset is stored as a data file in the smart home system (e.g., a PC) without strong authentication mechanisms. |
8 | This asset can be obtained if such devices are outsourced to a non-serious (untrusted) third-party service provider. |
9 | This asset can be obtained if such information is sent from the tracking system to a listener device in clear text and is captured by an attacker. |
10 | This asset can be found physically or digitally, e.g., on papers, CDs, DVDs, backup media, a PC, communication networks or databases. The information can be accessed by unauthorized people if not stored properly and securely. |
Threat ID | Possible Mitigation Approaches |
---|---|
Control access to the system using efficient biometric identifiers [49] | |
1 | Implement a user awareness program to make users aware of social engineering |
Implement multi-factor authentication | |
Avoid using insecure Wi-Fi, which gives hackers access to personal data | |
2 | Set up a secure network before using a home automation application |
Be aware of stolen or lost devices | |
Use a secure communication channel by utilizing a secure virtual private network (VPN) | |
3 | Limit network traffic such that it is accessible only to authorized users |
Develop a security awareness training program for smart home inhabitants | |
Use an intrusion detection system (IDS) / intrusion prevention system (IPS) | |
4 | Use encryption mechanisms for security data transmission [50] |
Perform frequent data backups to keep copies of sensitive data | |
Secure the physical locations of installed devices | |
5 | Provide secure access to device configuration interfaces |
Replace the default usability configuration of installed devices | |
Use commodity hardware and software to collect and examine network traffic [33,34] | |
6 | Create backups of the working system’s configurations |
Always monitor system’s performance, looking for misbehavior incidents | |
Apply a strong authentication mechanism such as fingerprint authentication [51] | |
7 | Offer awareness and training programs regarding system security |
Ensure that system configurations are secure and performed by authentic people | |
Restrict physical access to devices to only authentic people | |
8 | Avoid infrastructure outsourcing to a third-party service provider |
Modify default device configurations to achieve a better security level | |
Disable unnecessary location tracking services on mobile devices | |
9 | Develop a good understanding of user privacy concerns |
Track system behavior to identify any suspicious privacy leakage | |
Use only trusted and authentic networks (wired or wireless) | |
10 | Share information carefully and in a restricted manner |
Use only trusted providers to receive technical support for hardware failures in smart home |
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Ali, B.; Awad, A.I. Cyber and Physical Security Vulnerability Assessment for IoT-Based Smart Homes. Sensors 2018, 18, 817. https://doi.org/10.3390/s18030817
Ali B, Awad AI. Cyber and Physical Security Vulnerability Assessment for IoT-Based Smart Homes. Sensors. 2018; 18(3):817. https://doi.org/10.3390/s18030817
Chicago/Turabian StyleAli, Bako, and Ali Ismail Awad. 2018. "Cyber and Physical Security Vulnerability Assessment for IoT-Based Smart Homes" Sensors 18, no. 3: 817. https://doi.org/10.3390/s18030817
APA StyleAli, B., & Awad, A. I. (2018). Cyber and Physical Security Vulnerability Assessment for IoT-Based Smart Homes. Sensors, 18(3), 817. https://doi.org/10.3390/s18030817