DRV401 Datasheet, PDF(16/28 Page) Burr-Brown (TI) – Sensor Signal Conditioning IC for Closed-Loop Magnetic Current Sensor

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DRV401 Datasheet, PDF (16/28 Pages) Burr-Brown (TI) – Sensor Signal Conditioning IC for Closed-Loop Magnetic Current Sensor

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DRV401

SBVS070A â JUNE 2006 â REVISED OCTOBER 2006

COMPENSATION DRIVER

The compensation coil driver provides the driving current

for the compensation coil. A fully differential driver stage

offers high signal voltages to overcome the wire resistance

of the coil with only +5V supply. The compensation coil is

connected between ICOMP1 and ICOMP2, both generating an

analog voltage across the coil (see Figure 3) that turns into

current from the wire resistance (and eventually from the

inductance). The compensation current represents the

primary current transformed by the turns ratio. A shunt

resistor is connected in this loop and the high-precision

difference amplifier translates the voltage from this shunt

to an output voltage.

Both compensation driver outputs provide low impedance

over a wide frequency range to insure smooth transitions

between the closed-loop compensation frequency range

and the high-frequency range, where the primary winding

directly couples the primary current into the compensation

coil at a rate set by the winding ratio.

The two compensation driver outputs are designed with

protection circuitry to handle inductive energy. However,

additional external protection diodes might be necessary

for high current sensors.

For reliable operation, a wire break in the compensation

circuit can be detected. If the feedback loop is broken, the

integrating filter drives the outputs ICOMP1 and ICOMP2 to the

opposite rails. With one of these pins coming within 300mV

to ground, a comparator tests for a minimum current flowing

between ICOMP1 and ICOMP2. If this current stays below the

threshold current level for at least 100Âµs, the ERROR pin is

asserted active (low). The threshold current level for this test

is less than 57mA at 25Â°C and 65mA at â40Â°C, if the ICOMP

pins are fully railed (see the Typical Characteristics).

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For sensors with high winding resistance (compensation coil

resistance + RSHUNT) or connected to an external

compensation driver, this function should be disabled by

pulling the CCdiag pin low.

RMAX

V OUT

65mA

(1)

Where:

VOUT equals the peak voltage between ICOMP1 and ICOMP2

at a 65mA drive current.

RMAX equals the sum of the coil and the shunt resistance.

EXTERNAL COMPENSATION COIL DRIVER

An external driver for the compensation coil can be

connected to the ICOMP1 and ICOMP2 outputs. To prevent a

wire break indication, CCdiag has to be asserted low.

An external driver can provide both a higher drive voltage

and more drive current. It also moves the power

dissipation to the external transistors, thereby allowing a

higher winding resistance in the compensation coil and

more current. Figure 4 shows a block diagram of an

external compensation coil driver. To drive the buffer,

either one or both ICOMP outputs can be used. Note,

however, that the additional voltage gain could cause

instability of the loop. Therefore, the internal gain can be

reduced by approximately 8dB by asserting the GAIN pin

high. RSHUNT is connected to GND to allow for a

single-ended external compensation driver. The

differential amplifier can continue to sense the voltage,

and used for the gain and over-range comparator or

ERROR flag.

DRV401

ICOMP1

V+

External

Buffer

ICOMP2

Vâ

Compensation

Coil

RSHUNT

Figure 4. DRV401 with External Compensation Coil Driver and RSHUNT Connected to GND

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