Methods and systems for enabling or disabling a non-interfering mode in a telematics device are provided. The methods may include determining by a telematics server that a telematics device coupled to an asset communications bus of an asset may enter or exit a non-interfering mode. The methods may also include detecting the presence of a diagnostic tool on the asset communications bus.

The invention relates, inter alia, to a network device (10) which can be connected via electrical lines (15, 16) to other subscribers (18a, 18b, 12, 13) of a network (42), in particular a real-time intercom network (42), for transmitting audio and/or image information, wherein the network device (10) comprises at least one input-side terminal (22a) for connection to a power supply source (11) and at least one output-side terminal (22b) for connection to at least one second network device (12), wherein signals and operating voltage (PoE) can be transmitted via the terminals, using at least the following four layers (32, 33, 34, 35): a) PTP layer (precision time protocol), b) ethernet layer, c) data and/or information layer, d) PoE (power over ethernet) layer.

A first network device is connectable via electrical lines to a power supply and to other subscribers of a network for transmitting audio and/or image information. It has an input terminal connectable to the power supply, an output terminal connectable to a second network device, and signals and operating voltage are transmitted via the terminals using four layers. Equipment processes the signals received via the lines and the operating voltage in the first network device by receiving and/or retrieving or processing information relating to a maximally available PoE supply input on the input and receiving, or retrieving and or processing information relating to a power intake required at least by the second network device received and/or retrieved and/or further processed by the second network device. A tester is connected to the equipment for checking whether the supply input at the input is sufficient for the first and second network devices.

Systems for enabling or disabling a non-interfering mode in a telematics device are provided. The system is comprised of a telematics server and a telematics device. The telematics server determines that a telematics device coupled to an asset communications bus of an asset may enter or exit a non-interfering mode.

The invention relates, inter alia, to a network device (10) which can be connected via electrical lines (15, 16) to other subscribers (18a, 18b, 12, 13) of a network (42), in particular a real-time intercom network (42), for transmitting audio and/or image information, wherein the network device (10) comprises at least one input-side terminal (22a) for connection to a power supply source (11) and at least one output-side terminal (22b) for connection to at least one second network device (12), wherein signals and operating voltage (PoE) can be transmitted via the terminals, using at least the following four layers (32, 33, 34, 35): a) PTP layer (precision time protocol), b) ethernet layer, c) data and/or information layer, d) PoE (power over ethernet) layer.

One example method occurs at a switching fabric emulator providing an emulated switching fabric comprising emulated switching elements and associated packet queues, wherein the switching fabric emulator comprises at least one switching application-specific integrated circuit (ASIC) or programmable switching chip, the method comprising: during a test session: receiving, via at least a first physical port of the switching fabric emulator, packets from or to a system under test (SUT); detecting an occurrence of a dropped packet that happens while the packet is traversing the emulated switching fabric; encapsulating dropped packet data associated with the dropped packet, wherein the encapsulated dropped packet data indicates an emulated switching element or packet queue contributing to the occurrence of the dropped packet; and providing the encapsulated dropped packet data to an analyzer.

One example method occurs at a switching fabric emulator providing an emulated switching fabric comprising emulated switching elements and associated packet queues, wherein the switching fabric emulator comprises at least one switching application-specific integrated circuit (ASIC) or programmable switching chip, the method comprising: during a test session: receiving, via at least a first physical port of the switching fabric emulator, packets from or to a system under test (SUT); detecting an occurrence of a dropped packet that happens while the packet is traversing the emulated switching fabric; encapsulating dropped packet data associated with the dropped packet, wherein the encapsulated dropped packet data indicates an emulated switching element or packet queue contributing to the occurrence of the dropped packet; and providing the encapsulated dropped packet data to an analyzer.

A network device is described that injects probes for exercising its own forwarding rules (e.g., layer 2 and layer 3). One or more probe packets can be injected into an ingress pipeline of the network device using the agent executing on a local processor. The probes are detected before or after performing at least layer 2 and layer 3 lookups. Hardware in switching logic redirects the probes to an external testing system in order to verify the actual forwarding behavior applied to the probe packet. In order to deliver the probes to the external server, the network device performs an additional layer 3 lookup and generates an encapsulated packet incorporating results of a lookup on the probe packet. In this way, the external server can analyze the lookup on the probe packet to determine whether the lookup was performed correctly.

System and method for diagnosing the state of a device connected to one or more computer networks. The method can include gathering and analyzing a status and configuration of every computer network interface available on a device, gathering and analyzing the network configuration information on a device, and, if available, gathering of GPS configurations, status, and data. The method can also include testing of network connectivity for the device using a preset server as a control and the testing of network connectivity for the device to arbitrary networked resources.

A method and system for analyzing and measuring multiple sources of data over a communications network (18) so as to ascertain information or usage of one or more resources, such as resource servers (2). A data collection and processing means (20) collects and processes the data sources which are forwarded to a reporting server (34) as a combined data source made available to interested parties.