Difference between revisions of "Current sense"

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("lossless average inductor current sensing")
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If something blocks an electric from turning ("stalled"), the current rapidly increases far above normal levels -- then the [[motor driver]] needs to turn off the power before the motor, or the motor driver MOSFET, or both are destroyed.
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If something blocks an electric motor from turning ("stalled"), the current rapidly increases far above normal levels -- then the [[motor driver]] needs to turn off the power before the motor, or the motor driver MOSFET, or both are destroyed.
  
 
Systems that use a 4-20 mA current loop also need to measure current.
 
Systems that use a 4-20 mA current loop also need to measure current.

Revision as of 13:14, 15 March 2011

If something blocks an electric motor from turning ("stalled"), the current rapidly increases far above normal levels -- then the motor driver needs to turn off the power before the motor, or the motor driver MOSFET, or both are destroyed.

Systems that use a 4-20 mA current loop also need to measure current.

There are 3(?) basic techniques: for measuring current:

  • resistive shunt
  • low-side current shunt
    • high-side current shunt
  • magnetic field sense
  • MOSFET voltage
  • the "non-dissipative overcurrent protection", a kind of current mirror used in the L6208N ...
  • ... (any others I missed?)

resistive shunt

"What's All This Shunt Stuff, Anyhow?" by Bob Pease 2002 describes one way to custom-build a high-current shunt.

"What’s All This Wattmeter Stuff, Anyhow?" by Bob Pease 2002 describes how to use the previous shunt in a circuit to be spliced in the middle of an extension cord to measure true RMS watts flowing from a power outlet to a device under test. Even though a copper shunt has a pretty bad resistance variation with temperature (tempco), other parts in this circuit compensate for it.

low-side current shunt

Low-side is (electrically) the simplest.

For smaller motors, the current is usually measured by running the current through a shunt resistor to ground, and measuring the voltage across the resistor.

high-side current shunt

In situations where low-side sensing is difficult ( automobile electronics bonded to the "GND" car frame; other systems where it is inconvenient to put a resistor on the "lo" power wire), we turn to high-side sensing.

Maxim application note 746: "High-Side Current-Sense Measurement: Circuits and Principles"; Newark: high side current sense; Digikey: high side current sense; Linear: current sense circuit collection (why doesn't this include the Linear LTC6103 ?); Texas Instruments: "Current Sensor", Silicon Labs' current sensors. A few op amps can handle common-mode voltage well outside its power supply -- such as the TI INA117, which when powered by +/-15 V, can handle a common-mode voltage of +/-200 V. This is useful for high-side current sense and also 4-20 mA current loops.

magnetic field sense

For large motors, the current is measured by running the power wires through a magnetic field sensor -- either

Because magnetic field sensing is inherently non-contact, it works just as well high-side as low-side. ( "Closed-Loop Magnetic Current Sensor". )

MOSFET voltage

pseudo 'mirror' current sensing a MOSFET -- sampling the voltage across a MOSFET while it is turned on. That voltage is linear with current but varies with temperature. If the purpose of measuring current is to turn off the MOSFET before it overheats, the variation with temperature doesn't matter. (A true current mirror isn't useful for motors, right?)

This uses the turned-on resistance of the MOSFET as if it were a shunt resistor.

current estimation

Rather than directly measuring the actual current, many people measure something else that (they hope) is close enough to being proportional to the current.

lossless average inductor current sensing

The "lossless average inductor current sensing" technique:

The current through an inductor with some known internal parasitic resistance DCR can be sensed with a series resistor (Rs) and capacitor network connected in parallel with the inductor-resistor network. The designer picks the sense components Rs and C such that Rs*C -- the time constant of the RC network -- is close enough to L/DCR -- the time constant of the inductor resistor network -- then the voltage across C is proportional to the current through L. (IR3508Z data sheet [1])

   current through L == voltage across C * (1/DCR).