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Electrical termination
Electrical termination
Electrical termination
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SCSI terminator

In electronics, electrical termination is the practice of ending a transmission line with a device that matches the characteristic impedance of the line. Signal reflections occur where there is an impedance mismatch. Termination prevents signals from reflecting off the end of the transmission line. Reflections at the ends of unterminated transmission lines cause distortion, which can produce ambiguous digital signal levels and misoperation of digital systems. Reflections in analog signal systems cause such effects as video ghosting, or power loss in radio transmitter transmission lines.

Transmission lines

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Signal termination often requires the installation of a terminator at the beginning and end of a wire or cable to prevent an RF signal from being reflected back from each end, causing interference, or power loss. The terminator is usually placed at the end of a transmission line or daisy chain bus (such as in SCSI), and is designed to match the AC impedance of the cable and hence minimize signal reflections, and power losses. Less commonly, a terminator is also placed at the driving end of the wire or cable, if not already part of the signal-generating equipment.[1]

Radio frequency currents tend to reflect from discontinuities in the cable, such as connectors and joints, and travel back down the cable toward the source, causing interference as primary reflections. Secondary reflections can also occur at the cable starts, allowing interference to persist as repeated echoes of old data. These reflections also act as bottlenecks, preventing the signal power from reaching the destination.

Transmission line cables require impedance matching to carry electromagnetic signals with minimal reflections and power losses. The distinguishing feature of most transmission line cables is that they have uniform cross-sectional dimensions along their length, giving them a uniform electrical characteristic impedance. Signal terminators are designed to specifically match the characteristic impedances at both cable ends. For many systems, the terminator is a resistor, with a value chosen to match the characteristic impedance of the transmission line and chosen to have acceptably low parasitic inductance and capacitance at the frequencies relevant to the system. Examples include 75-ohm resistors often used to terminate 75-ohm video transmission coaxial cables.

Types of transmission line cables include balanced line such as ladder line, and twisted pairs (Cat-6 Ethernet, Parallel SCSI, ADSL, Landline Phone, XLR audio, USB, Firewire, Serial); and unbalanced lines such as coaxial cable (Radio antenna, CATV, 10BASE5 Ethernet).

Types of electrical and signal terminators

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Passive

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Passive terminators often consist of a single resistor; however, significantly reactive loads may require other passive components such as inductors, capacitors, or transformers.

Active

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Active terminators consist of a voltage regulator that keeps the voltage used for the terminating resistor(s) at a constant level.

Forced perfect termination

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Forced perfect termination

Forced perfect termination (FPT) can be used on single ended buses where diodes remove over and undershoot conditions. The signal is locked between two actively regulated voltage levels, which results in superior performance over a standard active terminator.[2]

Signal termination applications

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SCSI

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All parallel SCSI units use terminators. SCSI is primarily used for storage and backup. An active terminator is a type of single-ended SCSI terminator with a built-in voltage regulator to compensate for variations in terminator power.[citation needed]

Controller Area Network

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Controller area network, commonly known as CAN Bus, uses terminators consisting of a 120 ohm resistor.

Dummy load

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Main article: Dummy load

Dummy loads are commonly used in HF to EHF circuits.

Ethernet coaxial 50 ohm

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10BASE2 cable end signal terminator

10BASE2 networks absolutely must have proper termination with a 50 ohm BNC terminator. If the bus network is not properly terminated, too much power will be reflected, causing all of the computers on the bus to lose network connectivity.

Antenna network 75 ohm

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A terminating resistor for a television coaxial cable is often in the form of a cap, threaded to screw onto an F connector. Antenna cables are sometimes used for internet connections; however, RG-6 should not be used for 10BASE2 (which should use RG-58) as the impedance mismatch can cause phasing problems with the baseband signal.

Unibus

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Unibus terminator-and-bootstrap card from a PDP-11/34

The Digital Equipment Corporation minicomputer Unibus systems used terminator cards with 178 Ω pull-up resistors on the multi-drop address and data lines and 383 Ω on the single-drop signal lines.[3]

MIL-STD-1553

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Terminating resistor values of 78.7 ohms 2 watt 1% are used on the MIL-STD-1553 bus. At the two ends of the bus, resistors connect between the positive (high) and negative (low) signal wires either in internally terminated bus couplers or external connectorized terminators.

The MIL-STD-1553B bus must be terminated at both ends to minimize the effects of signal reflections that can cause waveform distortion and disruption or intermittent communications failures.

Optionally, a high-impedance terminator (1000 to 3000 ohms) may be used in vehicle applications to simulate a future load from an unspecified device.

Connectorized terminators are available with or without safety chains.

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Electrical termination

View on Grokipedia
from Grokipedia
Electrical termination is the practice of ending a with a device that matches the of the line. In , this ensures by preventing reflections in high-speed applications and manages electrical stress in power systems. Proper termination is essential for maintaining circuit performance, safety, and longevity across various applications, from low-voltage electronics to high-voltage power distribution. In high-speed digital circuits, electrical termination focuses on to absorb signal energy and eliminate reflections that could distort data. A termination , typically placed at the end of a , matches the line's —such as 120 ohms for twisted-pair cables—to prevent voltage overshoot or undershoot. Key types include series termination at the driver end, which uses a to dampen the initial wave, and parallel termination at the receiver, often employing Thevenin equivalents with two resistors for balanced lines. These techniques are critical in PCB design for signals exceeding 100 MHz, such as in DDR memory or PCI buses, where unterminated lines can cause or device damage. For power cables, particularly those rated 2.5 kV to 765 kV, terminations control dielectric stress at the shield's end and provide insulation against environmental factors. IEEE Std 48-2020 outlines test procedures for these terminations, classifying them by insulation levels and requiring evaluations for and impulse withstand to ensure reliability in outdoor or indoor settings. In shielded cables, terminations often incorporate stress cones or capacitive layers to distribute evenly, preventing failures like in high-voltage systems.

Fundamentals of Transmission Lines

Definition and Purpose of Termination

Electrical termination refers to the practice of connecting a load impedance at the end of a that matches the line's , thereby absorbing incident signals completely and preventing any reflection back toward the source. This matching ensures that the transmission line behaves as if it were infinite in length from the perspective of the propagating wave, eliminating discontinuities that would otherwise cause signal bounce. The primary purpose of electrical termination is to maintain in electronic systems by avoiding reflections that can distort waveforms, leading to issues such as overshoot, ringing, or errors in high-speed digital circuits and communication networks. Without proper termination, these reflections superimpose on the original signal, reducing effective bandwidth and potentially causing or system instability, particularly in applications like and where precise timing and are critical. By absorbing the signal energy, termination maximizes power transfer to the load and supports reliable operation across a wide range of frequencies. Transmission line theory, including the , was formalized in the late 19th century by , building on work by William Thomson (Lord Kelvin), to analyze signal propagation, , and dispersion in long-distance telegraph cables, laying the foundation for modern termination practices. The practice of matching termination to Z0Z_0 to prevent reflections gained prominence in the 20th century with higher-frequency applications. To illustrate, an unterminated transmission line behaves like shouting into a canyon, where the sound (or signal) echoes back due to the abrupt end, creating interference; in contrast, a properly terminated line acts as a sound-absorbing wall, capturing the wave without return, thus preserving clarity.

Characteristic Impedance

Characteristic impedance, denoted as Z0Z_0, is the ratio of the voltage to the current for a wave propagating in a single direction along a transmission line, behaving as if the line were infinitely long and thus independent of its actual length. This property arises from the distributed nature of the line's inductance and capacitance, making Z0Z_0 appear as a resistive value despite the line consisting of reactive elements. The value of Z0Z_0 is determined by the transmission line's geometry and materials, specifically through the LL per unit length and CC per unit length, given by the formula Z0=LCZ_0 = \sqrt{\frac{L}{C}}
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