1658: Difference between revisions

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|image=GR 1658 Close-Up.jpg
|image=GR 1658 Close-Up.jpg
|caption=General Radio 1658 RLC Digibridge
|caption=General Radio 1658 RLC Digibridge
|series=
|series=1685
|introduced=1978
|introduced=1978
|discontinued=1978+
|discontinued=1978+
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|manuals=
|manuals=
* [[Media:GR 1658 RCL Digibridge 1658-0120-D 05_1980.pdf|General Radio 1658 RLC Digibridge Manual 1658-0120-D 1980]]
* [[Media:GR 1658 RCL Digibridge 1658-0120-D 05_1980.pdf|General Radio 1658 RLC Digibridge Manual 1658-0120-D 1980]]
* [[Media:GR 1658 Operation Reference Information.pdf|General Radio 1658 Quick Reference Card 1658-0110-A]]
{{Catalog History}}
{{Catalog History}}
}}
}}
The {{Title|General Radio 1658 RLC Digibridge}} was available in {{Catalog 1978}} only.  
The {{Title|General Radio 1658 RLC Digibridge}} was available in {{Catalog 1978}} only.  


The Type 1658 Digibridge is a digital impedance meter and comparator utilizing microprocessor control. Basic accuracy is 0.1% using a five digit display for RCL and four digits for D/Q. It features a built in test fixture with the option for an extension cable. Measurements using 120 Hz or 1 kHz and series or parallel circuits are keyboard selectable. An optional communications IEEE 488 buss/handler interface is available. The 1658 is equipped with a comparator function for Go/No Go testing and sorting of components into logical "Bins".  The limits and sorting information is entered using the keyboard.  Using this function is possible to sort parts by percentage or value and display either. 
The Type 1658 Digibridge is a digital impedance meter and comparator utilizing microprocessor control. Basic accuracy is 0.1% using a five digit display for RLC, and four digits for D/Q.  
 
It features a built-in test fixture with the option for an extension cable. Measurements can be made at 120 Hz or 1 kHz, and series or parallel circuits are keyboard selectable.  
The measurements are made by the Quadrature Sampling method.  Using this method the standard and the unknown are in series and a sine wave is applied.  Four voltage measurements are taken across the standard and then the unknown at four different phases of the sine wave. Using their magnitude and phase difference the processor calculates the resultsIts interesting to note the 1658 uses three measurement rates. The slow rate takes five measurements, medium rate eight (Quadrature), and the high rate sixteen. Because the processor creates the test sine wave using a digital to analog converter it has exact phase information for its measurements and calculations. Because of this measurement technique no calibration is performed or required.
An optional IEEE 488 bus/handler interface is available. The 1658 is equipped with a comparator function for Go/No-Go testing and sorting of components into logical "Bins".   
 
Limits and sorting information is entered using the keyboard.  Using this function, it is possible to sort parts by percentage or value.   


The measurements are made by the quadrature sampling method, where the standard and the unknown are in series and a sine wave is applied. 
Four voltage measurements are taken across the standard and then the unknown at four different phases of the sine wave.
Using their magnitude and phase difference, the processor calculates the results. 
It is interesting to note the 1658 uses three measurement rates. The slow rate takes five measurements, medium rate takes eight (Quadrature), and the high rate takes sixteen.
Because the processor creates the test sine wave using a digital-to-analog converter, it has exact phase information for its measurements and calculations, eliminating the need for calibration.


==Specifications==
==Specifications==
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* '''Basic Accuracy:''' 0.1%
* '''Basic Accuracy:''' 0.1%
* '''Test Frequencies:''' 120 Hz and 1 kHz
* '''Test Frequencies:''' 120 Hz and 1 kHz


==Links==
==Links==
* See also [[1657|1657 Digibridge]]


==Photos==
==Photos==
<gallery>
<gallery>
GR 1658 Front A.jpg
GR 1658 Front A.jpg
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GR 1658 Power Supply Close-Up.jpg
GR 1658 Power Supply Close-Up.jpg
GR 1658 Display Board Component Side.jpg
GR 1658 Display Board Component Side.jpg
GR 1658 Main Board Foil Side.jpg
GR 1658 Display Board Component Side B.jpg
GR 1658 Display Board Foil Side.jpg
GR 1658 Display Board Foil Side.jpg
GR 1658 Main Board Component Side.jpg
GR 1658 Main Board Foil Side.jpg
GR 1658 Keypad.jpg
GR 1658 Keypad.jpg
GR 1658 Operation Reference Information Color.jpg
GR 1658 Operation Reference Information Color.jpg

Latest revision as of 20:00, 12 June 2024

General Radio 1658
RLC Digibridge
General Radio 1658 RLC Digibridge

Available from 1978 to 1978+

Manuals
Catalog History
 Document Year Page
Catalog78 1978 24
(All manuals in PDF format unless noted otherwise)

The General Radio 1658 RLC Digibridge was available in Catalog 1978 only.

The Type 1658 Digibridge is a digital impedance meter and comparator utilizing microprocessor control. Basic accuracy is 0.1% using a five digit display for RLC, and four digits for D/Q. It features a built-in test fixture with the option for an extension cable. Measurements can be made at 120 Hz or 1 kHz, and series or parallel circuits are keyboard selectable. An optional IEEE 488 bus/handler interface is available. The 1658 is equipped with a comparator function for Go/No-Go testing and sorting of components into logical "Bins". Limits and sorting information is entered using the keyboard. Using this function, it is possible to sort parts by percentage or value.

The measurements are made by the quadrature sampling method, where the standard and the unknown are in series and a sine wave is applied. Four voltage measurements are taken across the standard and then the unknown at four different phases of the sine wave. Using their magnitude and phase difference, the processor calculates the results. It is interesting to note the 1658 uses three measurement rates. The slow rate takes five measurements, medium rate takes eight (Quadrature), and the high rate takes sixteen. Because the processor creates the test sine wave using a digital-to-analog converter, it has exact phase information for its measurements and calculations, eliminating the need for calibration.

Specifications

  • Measurement Ranges
  • Resistance: 0.0001 Ω to 9.9999 MΩ at 1 kHz, 0.0001 Ω to 99.999 MΩ at 120 Hz
  • Inductance: .00001 mH to 999.99 H at 1 kHz, 0.0001 mH to 9999.9 H at 120 Hz
  • Capacitance: .00001 nF to 999.99 μF at 1 kHz, 0.0001 nF to 99999 μF at 120 Hz
  • Dissipation Factor: .0001 to 9.999
  • Q Factor: 00.01 to 999.9 for L/Q, .0001 to 9.999 for R/Q
  • Basic Accuracy: 0.1%
  • Test Frequencies: 120 Hz and 1 kHz

Links

Photos