Related to "transmit telemetry"

Telemetry is an automated communications process by which measurements and other data are collected at remote or inaccessible points and transmitted to receiving equipment for monitoring.[1] The word is derived from Greek roots: tele = remote, and metron = measure. Systems that need external instructions and data to operate require the counterpart of telemetry, telecommand.[2]

Although the term commonly refers to wireless data transfer mechanisms (e.g., using radio, ultrasonic, or infrared systems), it also encompasses data transferred over other media such as a telephone or computer network, optical link or other wired communications like power line carriers. Many modern telemetry systems take advantage of the low cost and ubiquity of GSM networks by using SMS to receive and transmit telemetry data.

telemeter is a device used to remotely measure any quantity. It consists of a sensor, a transmission path, and a display, recording, or control device. Telemeters are the physical devices used in telemetry. Electronic devices are widely used in telemetry and can be wireless or hard-wired, analog or digital. Other technologies are also possible, such as mechanical, hydraulic and optical.[3]

Telemetry may be commutated to allow the transmission of multiple data streams in a fixed frame.

Description:

Telemetry is an automated communications process by which measurements and other data are collected at remote or inaccessible points and transmitted to receiving equipment for monitoring.[1] The word is derived from Greek roots: tele = remote, and metron = measure. Systems that need external instructions and data to operate require the counterpart of telemetry, telecommand.[2]

Although the term commonly refers to wireless data transfer mechanisms (e.g., using radio, ultrasonic, or infrared systems), it also encompasses data transferred over other media such as a telephone or computer network, optical link or other wired communications like power line carriers. Many modern telemetry systems take advantage of the low cost and ubiquity of GSM networks by using SMS to receive and transmit telemetry data.

telemeter is a device used to remotely measure any quantity. It consists of a sensor, a transmission path, and a display, recording, or control device. Telemeters are the physical devices used in telemetry. Electronic devices are widely used in telemetry and can be wireless or hard-wired, analog or digital. Other technologies are also possible, such as mechanical, hydraulic and optical.[3]

Telemetry may be commutated to allow the transmission of multiple data streams in a fixed frame.

Related Keyphrases:

wireless data transfer mechanisms | Many modern telemetry systems | multiple data streams | communications process | transmit telemetry | external instructions | Electronic devices | inaccessible points | power line carriers | transmission path | physical devices | computer network | control device | communications | optical link

Description:

Solution

With the currently available technologies Fiber Optic Temperature sensors stand out clearly to be the most suitable sensors for Emobility applications at higher voltages (250V+). The major benefits of Fiber optic Temperature sensors are: 

1. Safety: Fiber optics are safe – highest dielectric strength, ~1pC, tested up to 1500kV

2. Noise: Sensor are immune to electric, chemical and magnetic environments. Being used without any isolation, in applications that has 1500kV+ voltage, up to 25 Tesla magnetic field and chemical environment ranging from 0 to 14pH without any interference to the sensory readings.

3. Size: Ultra small sensors (Diameter of up to 0.4mm) to fit into tiniest spaces. 

4. Linearity: Fiber optic sensors transmit light signals through glass, the purest form of silica. The sensors are linear and does not need any compensation and special algorithms.

5. Response Time: Fiber optic temperature system has a milliseconds response level. Response rate varies between 1ms to 200ms depending on the type of monitor selected for the application. 

6. Repeatability: Fiber Optic temperature sensors are very stable and repeatable over the entire range without getting influenced by and external fields.

Related Keyphrases:

available technologies Fiber Optic Temperature sensors | Fiber optic temperature system | Fiber optic sensors | Ultra small sensors | 25 Tesla magnetic field | Emobility applications | magnetic environments | suitable sensors | Response rate varies | chemical environment | dielectric strength | Fiber optics | external fields | major benefits

Description:

Solution: Rugged Fiber Optic Temperature Sensors

With the currently available technologies Fiber Optic Temperature sensors stand out clearly to be the most suitable sensors for Emobility applications at higher voltages (250V+). The major benefits of Fiber optic Temperature sensors are:

  1. Safety: Fiber optics are safe – highest dielectric strength, ~1pC, tested up to 1500kV
  2. Noise: Sensor are immune to electric, chemical and magnetic environments. Being used without any isolation, in applications that has 1500kV+ voltage, up to 25 Tesla magnetic field and chemical environment ranging from 0 to 14pH without any interference to the sensory readings.
  3. Size: Ultra small sensors (Diameter of up to 0.4mm) to fit into tiniest spaces.
  4. Linearity: Fiber optic sensors transmit light signals through glass, the purest form of silica. The sensors are linear and does not need any compensation and special algorithms.
  5. Response Time: Fiber optic temperature system has a milliseconds response level. Response rate varies between 1ms to 200ms depending on the type of monitor selected for the application.
  6. Repeatability: Fiber Optic temperature sensors are very stable and repeatable over the entire range without getting influenced by and external fields.

Related Keyphrases:

available technologies Fiber Optic Temperature sensors | Fiber Optic Temperature SensorsWith | Fiber optic temperature system | Fiber optic sensors | Ultra small sensors | 25 Tesla magnetic field | Emobility applications | magnetic environments | suitable sensors | Response rate varies | chemical environment | dielectric strength | Fiber optics | external fields | response level