| CVE |
Vendors |
Products |
Updated |
CVSS v3.1 |
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Observable Response Discrepancy in SICK FTMg AIR FLOW SENSOR with Partnumbers 1100214, 1100215, 1100216, 1120114, 1120116, 1122524, 1122526 allows a remote attacker
to gain information about valid usernames by analyzing challenge responses from the server via the
REST interface.
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Use of Password Hash Instead of Password for Authentication in SICK FTMg AIR
FLOW SENSOR with Partnumbers 1100214, 1100215, 1100216, 1120114, 1120116, 1122524, 1122526
allows an unprivileged remote attacker to use a password hash instead of an actual password to login
to a valid user account via the REST interface.
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Cleartext Storage of Sensitive Information in SICK FTMg AIR FLOW SENSOR with
Partnumbers 1100214, 1100215, 1100216, 1120114, 1120116, 1122524, 1122526 allows a remote
attacker to potentially steal user credentials that are stored in the user’s browsers local storage via
cross-site-scripting attacks.
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Uncontrolled Resource Consumption in SICK FTMg AIR FLOW SENSOR with Partnumbers 1100214, 1100215, 1100216, 1120114, 1120116, 1122524, 1122526 allows an remote attacker to influence the availability of the webserver by invocing a Slowloris style attack via HTTP requests.
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| A remote unprivileged attacker can intercept the communication via e.g. Man-In-The-Middle, due to the absence of Transport Layer Security (TLS) in the SICK EventCam App. This lack of encryption in the communication channel can lead to the unauthorized disclosure of sensitive information. The attacker can exploit this weakness to eavesdrop on the communication between the EventCam App and the Client, and potentially manipulate the data being transmitted. |
| A remote unprivileged attacker can modify and access configuration settings on the EventCam App due to the absence of API authentication. The lack of authentication in the API allows the attacker to potentially compromise the functionality of the EventCam App. |
| Unauthenticated CROWN APIs allow access to critical functions. This leads to the accessibility of large parts of the web application without authentication. |
| Due to missing input validation during one step of the firmware update process, the product
is vulnerable to remote code execution. With network access and the user level ”Service”, an attacker
can execute arbitrary system commands in the root user’s contexts. |
| Since the firmware update is not validated, an attacker can install modified firmware on the
device. This has a high impact on the availabilty, integrity and confidentiality up to the complete compromise of the device. |
| The product is vulnerable to pass-the-hash attacks in combination with hardcoded credentials of hidden user levels. This means that an attacker can log in with the hidden user levels and gain
full access to the device. |
| A remote unprivileged attacker can intercept the communication via e.g. Man-In-The-Middle, due to the absence of Transport Layer Security (TLS) in the SICK LMS5xx. This lack of encryption in the communication channel can lead to the unauthorized disclosure of sensitive information. The attacker can exploit this weakness to eavesdrop on the communication between the LMS5xx and the Client, and potentially manipulate the data being transmitted. |
| A remote unprivileged attacker can sent multiple packages to the LMS5xx to disrupt its availability through a TCP SYN-based denial-of-service (DDoS) attack.
By exploiting this vulnerability, an attacker can flood the targeted LMS5xx with a high volume of TCP SYN requests, overwhelming its resources and causing it to become unresponsive or unavailable for legitimate users. |
| The LMS5xx uses hard-coded credentials, which potentially allow low-skilled
unauthorized remote attackers to reconfigure settings and /or disrupt the functionality of the device. |
| The LMS5xx uses weak hash generation methods, resulting in the creation of insecure hashs. If an attacker manages to retrieve the hash, it could lead to collision attacks and the potential retrieval of the password. |
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A remote unauthorized attacker may connect to the SIM1012, interact with the device and
change configuration settings. The adversary may also reset the SIM and in the worst case upload a
new firmware version to the device.
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| Lua apps can be deployed, removed, started, reloaded or stopped without authorization via
AppManager. This allows an attacker to remove legitimate apps creating a DoS attack, read and write
files or load apps that use all features of the product available to a customer. |
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Files or Directories Accessible to External Parties in RDT400 in SICK APU allows an
unprivileged remote attacker to download various files from the server via HTTP requests.
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Insufficient Control Flow Management in RDT400 in SICK APU allows an unprivileged remote attacker to potentially enable hidden functionality via HTTP requests.
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Improper Restriction of Excessive Authentication Attempts in RDT400 in SICK APU
allows an unprivileged remote attacker to guess the password via trial-and-error as the login attempts
are not limited.
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Modification of Assumed-Immutable Data (MAID) in RDT400 in SICK APU allows an
unprivileged remote attacker to make the site unable to load necessary strings via changing file paths
using HTTP requests.
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