IC-MA_14 Datasheet, PDF(12/19 Page) IC-Haus GmbH – 8-BIT ANGULAR HALL SENSOR / ENCODER

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IC-MA_14 Datasheet, PDF (12/19 Pages) IC-Haus GmbH – 8-BIT ANGULAR HALL SENSOR / ENCODER

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iC-MA

8-BIT ANGULAR HALL SENSOR / ENCODER

ANALOG MODES OF OPERATION

Rev C1, Page 12/19

Mode NEN CFG1 CFG2 CFG3

Analog

S-Sensor low low low low

D-Sensor low open low low

D-Sensor low high low low

Port A

PSIN

Port B

VREF

NSIN

Port C

PCOS

Port D Res. Comment

GAIN

NCOS

PRM

In the analog modes of operation the ampliï¬ed Hall

voltages are available at the output ports. The sine/

cosine output signals are controlled to have stable am-

plitudes of 1 V and referenced to a DC value equivalent

to half of the supply voltage (VREF). Due to the inter-

nal signal conditioning unit, no special adjustment is

required. An externally connected interpolator can be

used if further trimming of the output signals is desired.

PSIN

NCOS

VREF

NSIN

PCOS

GAIN

100 200 300 400 500 600 700

Time [Âµs]

Figure 6: Analog mode output signals after switch-

ing on the device

S-Sensor Mode

After the device has been activated via NEN = low the

sensor is set to its operating point. All signals are

referenced to half the supply voltage (VREF). In S-

Sensor mode this potential is available at port B. Ports

A and C output the sine and cosine Hall voltages set to

2 Vss. The angle can be calculated from the relation of

the sine voltage (difference in voltage PSIN to VREF)

to the cosine voltage (difference in voltage PCOS to

VREF). The device supplies an angle which remains

non-ambiguous over a 360Â° rotation of the permanent

magnet.

Signal GAIN allows conclusions to be drawn as to the

operating point of the sensor. This is inï¬uenced by

the amplitude of the magnetic ï¬eld, the sensor supply

voltage and temperature. The higher the GAIN poten-

tial, the greater the necessary ampliï¬cation of the Hall

voltages; the external magnetic ï¬eld is smaller. Be-

sides recording the direction of magnetization of the

permanent magnet the distance between the magnet

and sensor may also be assessed using the GAIN sig-

nal. If the gain is insufï¬cient to boost the Hall voltages

to 2 Vss the amplitude control reaches its upper limit

and the output amplitude becomes smaller.

The GAIN signal can be used to adjust the permanent

magnet. If the central point of both the magnet and

sensor iC-MA are the same the GAIN signal has no

harmonics. A misaligned sensor must readjust the op-

erating point depending on the angle; the GAIN signal

varies in amplitude. To adjust the sensor to the magnet

this must be shifted along its X- and Y-axis so that the

GAIN signal has to readjust as little as possible.

D-Sensor Mode

In D-Sensor mode differential sine (pin A and pin B)

and cosine (pin C and pin D) signals are supplied at

the output; as opposed to S-Sensor mode inverted Hall

signals are now also available at the ports. The advan-

tage of this mode of operation is the doubled signal

amplitude of the differential Hall voltages and the lack

of dependence on reference voltage VREF. The an-

gle is now calculated via the ratio of the difference be-

tween PSIN and NSIN and between PCOS and NCOS.

D-Sensor mode is also available with a reduced power

consumption (PRM or Power Reduced Mode). In this

mode the Hall sensor is supplied with current less fre-

quently, reducing the power consumption. Here it must

be observed that the maximum rotating frequency also

drops by a factor of 2.

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