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HAL805-1 Datasheet, PDF (23/30 Pages) Micronas – Programmable Linear Hall-Effect Sensor
DATA SHEET
HAL 805
4. Application Notes
4.1. Application Circuit
For EMC protection, it is recommended to connect one
ceramic 4.7 nF capacitor each between ground and
the supply voltage, respectively the output voltage pin.
In addition, the input of the controller unit should be
pulled-down with a 4.7 kOhm resistor and a ceramic
4.7 nF capacitor.
Please note that during programming, the sensor will
be supplied repeatedly with the programming voltage
of 12.5 V for 100 ms. All components connected to the
VDD line at this time must be able to resist this voltage.
VDD
4.7 nF
HAL805
OUT
4.7 nF
4.7 nF
GND
μC
4.7 kΩ
Fig. 4–1: Recommended application circuit
4.2. Use of two HAL805 in Parallel
Two different HAL805 sensors which are operated in
parallel to the same supply and ground line can be
programmed individually. In order to select the IC
which should be programmed, both Hall ICs are inacti-
vated by the “Deactivate” command on the common
supply line. Then, the appropriate IC is activated by an
“Activate” pulse on its output. Only the activated sen-
sor will react to all following read, write, and program
commands. If the second IC has to be programmed,
the “Deactivate” command is sent again, and the sec-
ond IC can be selected.
VDD
OUT A & Select A
10 nF
HAL 805
Sensor A
4.7 nF
HAL 805 OUT B & Select B
Sensor B
4.7 nF
GND
Fig. 4–2: Parallel operation of two HAL 805
4.3. Temperature Compensation
The relationship between the temperature coefficient
of the magnet and the corresponding TC and TCSQ
codes for linear compensation is given in the following
table. In addition to the linear change of the magnetic
field with temperature, the curvature can be adjusted
as well. For this purpose, other TC and TCSQ combi-
nations are required which are not shown in the table.
Please contact Micronas for more detailed information
on this higher order temperature compensation.
The HAL810, HAL815, and HAL805 contain the same
temperature compensation circuits. If an optimal set-
ting for the HAL810, HAL815 is already available, the
same settings may be used for the HAL805.
Temperature
TC
Coefficient of
Magnet (ppm/K)
400
31
300
28
200
24
100
21
0
18
−50
17
−90
16
−130
15
−170
14
−200
13
−240
12
−280
11
−320
10
−360
9
−410
8
−450
7
−500
6
−550
5
−600
4
−650
3
−700
2
−750
1
TCSQ
6
7
8
9
10
10
11
11
11
12
12
12
13
13
13
13
14
14
14
14
15
15
Micronas
Feb. 14, 2006; 6251-513-3DS
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