Understanding Differential Inputs in Microelectronics by Sedra-Smith

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SUMMARY

This discussion centers on the application of differential inputs in microelectronics, specifically referencing the MOS/BJT differential pair as described in Sedra-Smith's textbook. It clarifies that differential inputs can indeed be both DC and AC signals, contrary to the common misconception that they are limited to AC. The conversation highlights the necessity of DC biasing in high-speed differential technologies and discusses practical applications, such as temperature measurement using thermocouples. The differential pair configuration is noted for its versatility, allowing for various input and output modes while enhancing common mode rejection.

PREREQUISITES
  • Understanding of MOSFET and BJT operation
  • Familiarity with differential amplifier configurations
  • Knowledge of AC and DC signal characteristics
  • Basic principles of temperature measurement using thermocouples
NEXT STEPS
  • Study the design and operation of MOS/BJT differential pairs in detail
  • Explore the concept of common mode rejection in differential amplifiers
  • Investigate the role of DC biasing in high-speed differential signaling
  • Learn about practical applications of differential amplifiers in sensor systems
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Electrical engineers, microelectronics students, and professionals involved in designing and implementing differential amplifiers and related technologies.

eliotsbowe
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Hello, I'm studying the MOS/BJT differential pair on Microelectronics by Sedra-Smith.
The book refers to voltage signals with the following notations:

gif.latex?V_{AB}.gif
= DC voltage
gif.latex?v_{ab}.gif
= AC voltage
gif.latex?v_{AB}.gif
= generic time-varying voltage

When it comes to differential pairs, it uses a quite confusing notation for differential inputs: they are always called
gif.latex?v_{id}.gif
, like they could be only AC signals, but I'm not positive on this restriction.

I happened to find some exercises on the MOS differential pair based on Sedra-Smith's figures (http://www.ece.utah.edu/~ccharles/ece3110/Homework/Assignment3.pdf) and they seem to confirm that
gif.latex?v_{id}.gif
may be both a DC and an AC signal. Is this definitely correct?

If it is, I have a second question: what would be the point of applying a DC differential input to a differential pair? I mean, is there any application in the real life in which a DC voltage needs to be amplified?Thanks in advance for your help.
 
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There is no universal nomenclature. Depends on which datasheet or book.

Many (if not most) high speed differential technologies need their receivers to be biased to a specific DC voltage in order to function correctly. This can be accomplished by using a driver that conforms (such as with ECL), or by AC coupling and incorporating biasing into receiver (self biasing).
 
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eliotsbowe said:
If it is, I have a second question: what would be the point of applying a DC differential input to a differential pair? I mean, is there any application in the real life in which a DC voltage needs to be amplified?
You might position multiple thermocouples (each with its own buffer) around a heatsink, and the temperature difference between locations can be gauged by measuring the voltage difference between any pair of thermocouples. So use a differential amp for this.

The term DC is often used to simply mean "of much lower frequency than the principal time-varying signals", and means the differential amplifier inputs are directly coupled and can operate right down to DC (so the diff amp design can't use capacitor coupling).
 
If it is, I have a second question: what would be the point of applying a DC differential input to a differential pair? I mean, is there any application in the real life in which a DC voltage needs to be amplified?

The differential input pair or longtail pair is one of the most used configurations at all frequencies, including zero or DC.

This is partly because it is easy to build in compensations for disturbing influences like temperature and because you can stably and controllably achieve substantial voltage gain.

The configuration can not only offer differential input put also single ended input, and differential oputput so can be used in four modes.

Single ended input single ended output
Differential input single ended output
Single ended input differential output
Differential input differential output

Use of the differential input increases common mode rejection (noise etc).

Use of the differential output allows driving of such devices as the opposing plates of electrostatic deflection systems eg in cathode ray tubes.

The differential output also allows phase splitting operations such as driving push-pull amplifiers.

All forms of amplifying devices can be used in this mode, valves (tubes), transistors, FETs, even op amps.

go well
 
I think the answers made my ideas clear, many thanks to everybody :smile:
 

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