telemetry

te·lem·e·try (tə-lĕmʹĭ-trē) n.
The science and technology of automatic measurement and transmission of data by wire, radio, or other means from remote sources, as from space vehicles, to receiving stations for recording and analysis.
  tel'e·metʹric (tĕl'ə-mĕtʹrĭk) or tel'e·metʹri·cal (-rĭ-kəl) adj. tel'e·metʹri·cal·ly adv.

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Highly automated communications process by which data are collected from instruments located at remote or inaccessible points and transmitted to receiving equipment for measurement, monitoring, display, and recording.

Transmission of the information may be over wires or, more commonly, by radio. The technique is used extensively for oil-pipeline monitoring and control systems and in oceanography and meteorology. Telemetry for rockets and satellites bloomed in the 1950s and has continued to grow in complexity and in breadth of application. Data can be transmitted from inside internal-combustion engines during tests, from steam turbines in operation, and from manned and unmanned spacecraft. Major scientific applications include biomedical research and remote observation of operations with highly radioactive material.

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Introduction

      highly automated (automation) communications process by which measurements are made and other data collected at remote or inaccessible points and transmitted to receiving equipment for monitoring, display, and recording. Originally, the information was sent over wires, but modern telemetry more commonly uses radio transmission. Basically, the process is the same in either case. Among the major applications are monitoring electric-power plants, gathering meteorological data, and monitoring manned and unmanned space flights.

      The original telemetry systems were termed supervisory because they were used to monitor electric power distribution. In the first such system, installed in Chicago in 1912, telephone lines were used for transmitting data on the operation of a number of electric-power plants to a central office. Such systems spread to other fields besides power networks and underwent extensive improvements, culminating in the introduction in 1960 of the so-called interrogation-reply principle, a highly automated arrangement in which the transmitter-receiver facility at the measuring point automatically transmits needed data only on being signalled to do so. The technique is applied extensively throughout the world in such fields as oil-pipeline (petroleum) monitor-control systems and oceanography, in which a network of buoys transmits information on demand to a master station.

      Aerospace telemetry dates from the 1930s, with the development of the balloon-borne radiosonde, a device that automatically measures such meteorological data as temperature, barometric pressure, and humidity and that sends the information to an Earth station by radio. Aerospace telemetry for rockets and satellites was inaugurated with the Soviet satellite Sputnik, launched in 1957, and systems have grown in size and complexity since then. Observatory satellites have performed as many as 50 different experiments and observations, with all data telemetered back to a ground station. The techniques developed in aerospace have been successfully applied to many industrial operations, including the transmission of data from inside internal-combustion engines during tests, from steam turbines in operation, and from conveyor belts inside mass-production ovens.

Telemetering systems and components.
      A typical telemetering system consists of an input device called a transducer, a medium of transmission (usually radio waves), equipment for receiving and processing the signal, and recording or display equipment.

      The transducer converts the physical stimulus to be measured, such as temperature, vibration, or pressure, into an electrical signal and thus operates as the actual measuring instrument. Transducers can take many forms. They can be self-generating or externally energized. An example of the self-generating type is a vibration sensor based on the use of a piezoelectric material—i.e., one that produces an electrical signal when it is mechanically deformed. Many externally energized transducers operate by producing an electrical signal in response to mechanical deformation. Typical physical inputs producing such deformations are pressure, mechanical stress, and acceleration. A simple mechanical transducer-sensing device is a strain gauge based on the change in electrical resistance of a wire or a semiconductor material under strain. Another externally energized transducer, called the variable-reluctance type, is one in which the magnetic circuit is broken by an air gap. The mechanical movement to be measured is used to change this air gap, thus changing the reluctance, or opposition, to the production of a magnetic field in the circuit. The change in reluctance is then translated into an electrical signal.

      Temperature sensors can be divided into two classifications: temperature-dependent resistance elements and self-generating thermocouples (thermocouple). Thermistors (thermistor) are of the first type; they have a high negative temperature coefficient—i.e., their resistance drops very rapidly as the temperature increases. The thermistor is small and provides rapid response to changes in temperature. Thermocouples are wire junctions of dissimilar metals that produce an electrical current when heated; they have a very low output, and each must be used with a second thermocouple held at a constant cold temperature for a reference point.

      There are many types of specialized sensors and transducer systems. One is the previously mentioned radiosonde system, designed specifically to radio weather data from a balloon to a ground station. Most weather-sensing and transmitting elements measure temperature, pressure, and humidity. In manned space probes, sensors for measuring such factors as the astronaut's blood pressure, heartbeat, and breathing rate are employed. Sensors have also been developed to indicate the rate of flow of a fluid through a pipe.

      Communications links. Communications facilities for telemetry consist primarily of radio or wire links. Alternatives such as light beams or sonic signals are used in a few cases, but environmental factors (e.g., atmospheric obstructions) and local masking noises make them impractical for most applications.

      Radio communication is used for aerospace work and for supervisory systems in which it is impractical to provide wire line links. For public utility installations in built-up areas, radio communication is usually ruled out by the difficulty of finding antenna sites and unobstructed line-of-sight radio paths. In such cases, cables and line links are used.

      An important consideration in radio links is the choice of operating frequency, a choice limited to bands allocated by international agreement. Propagation varies enormously over the range of frequencies involved. For aerospace applications in which transmissions must penetrate the atmosphere, the frequency range is 100 megahertz (100,000,000 cycles per second) to 10,000 megahertz. Line links for supervisory applications usually employ a comparatively narrow band. They may utilize the whole or only a section of a conventional voice channel with a bandwidth of 3,000 hertz (cycles per second). The link may be either a direct wire circuit or one of the channels in a carrier communications system.

multiplexing and sampling.
      A telemetry system ordinarily must handle more than one channel of information (e.g., routine measurements from an orbiting satellite, or flow rate and reservoir levels in a water-distribution network). These data-measurement channels are brought together by a process known as multiplexing, which combines the channels into one composite signal for transmission over the communications link. Multiplexing may be based on either a time division or a frequency division. In time division, channels are combined one after another in time sequence; in frequency division, each channel is assigned on an individually allocated, discrete frequency band, and these bands are then combined for simultaneous transmission. Finally, data may be handled within the telemetry system in a continuous (analog) or discrete (digital) way. The latter systems are relatively more complex because it is necessary to convert analog signals to digital form, a process known as encoding, for a purely digital arrangement.

      Time-division multiplexing involves a sequential action in which samples are selected in turn from a number of different measurement channels for transmission to the receiving point. In fixed cycle selection, a switching device connects a particular channel to the outgoing communications link in accordance with a prearranged sequence.

      With a so-called address-reply system, data are sent only as a result of a command signal: sampling is in accordance with a predetermined scanning program. The program is flexible because it can be arranged to meet priority requirements for information, as, for instance, when an alarm condition develops.

Transmission.
      A process called modulation is used to impress the information on the carrier frequency. Of the many design choices that must be made, that of the modulation method is among the most important. Not only does it have a direct influence on system performance but it also tends to define areas of design in both the sender and the receiver.

      Modulation methods fall into two divisions. The first includes amplitude and frequency modulation (as in commercial AM and FM broadcasting) and related types. These related types include two pulse-based methods in which several pulses are spaced out in time, each pulse representing one information channel. The two types are pulse-width (or pulse-duration) modulation and pulse-position modulation. In the first, the information produces variations in the width (or duration) of the pulse; in the second, the variation is in the position of the pulse with respect to time. In the second main class, pulse-code modulation, the information is coded digitally into groups of pulses and then transmitted.

      In most telemetering systems, modulation is carried out in two stages. First, the signal modulates a subcarrier (a radio-frequency wave the frequency of which is below that of the final carrier), and then the modulated subcarrier in turn modulates the output carrier. Frequency modulation is used in many of these systems to impress the telemetry information on the subcarrier. If frequency-division multiplexing is used to combine a group of these frequency-modulated subcarrier channels, the system is known as an FM/FM system.

Processing the received signal.
      At the receiving end of the telemetry chain, two tasks must be performed: the original measurement data must be extracted from the received signal, and it must be presented or displayed in intelligible form. The extraction of the data takes place in two stages and is the reverse of the steps taken in producing the modulated composite transmitting signal. Initial demodulation produces the modulated subcarrier; this subcarrier is then split up into its original measurement channels by demultiplexing (the reverse of multiplexing). The separated signals are fed individually to their respective points in the presentation system. Data is presented in “real time”—that is, at the instant the variable is being measured—and in one or more recorded forms. Magnetic tape is the most widely used recording medium.

      The presentation of aerospace data differs from that of supervisory data. For the routine requirements of the latter, formal diagram displays normally are provided, together with printout of the data by electric typewriter. Aerospace systems, on the other hand, being experimental in nature, generally display a wide range of measurements. Almost without exception, data are recorded in a form suitable for processing by computers (computer).

Special applications and techniques.
      New applications of telemetry are constantly appearing, particularly in the fields of research and scientific investigation. An important area is biomedical research, in which biological (biology) information is telemetered from inside patients by means of microminiature transmitters that are either swallowed or surgically implanted. External monitoring of body conditions can be carried out with surface transducers.

      Another scientific area in which telemetry is applied is oceanography. In this case, unmanned instrumented buoys are interrogated by a central master station at appropriate intervals. Both oceanographic data (e.g., water temperature and salinity) and surface meteorological information are recorded, ready to be transmitted to the master station in response to interrogation.

      In mechanical engineering, information is transmitted from inside prime movers (e.g., electric, gas, steam, and diesel engines) over various types of radio links to an external receiver. The information normally includes temperature and pressure.

      Telemetry is often provided by television-like facilities usually employing a low-bandwidth communications link. This type of facility is advantageous when a visual indication is desired of a process inaccessible to humans. Applications include rocket-motor testing and remote observation of operations with highly radioactive material.

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Universalium. 2010.

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