HAL1820UA-A - Micronas - searchdatasheet.com

Hardware

Documentation

Programmable Linear

Hall Effect Sensor

HAL® 1820

Edition July 3, 2013

DSH000158_003EN

Data Sheet

HAL 1820 DATA SHEET

2July 3, 2013; DSH000158_003EN Micronas

The information and data contained in this document

are believed to be accurate and reliable. The software

and proprietary information contained therein may be

protected by copyright, patent, trademark and/or other

intellectual property rights of Micronas. All rights not

expressly granted remain reserved by Micronas.

Micronas assumes no liability for errors and gives no

warranty representation or guarantee regarding the

suitability of its products for any particular purpose due

to these specifications.

By this publication, Micronas does not assume respon-

sibility for patent infringements or other rights of third

parties which may result from its use. Commercial con-

ditions, product availability and delivery are exclusively

subject to the respective order confirmation.

Any information and data which may be provided in the

document can and do vary in different applications,

and actual performance may vary over time.

All operating parameters must be validated for each

customer application by customers’ technical experts.

Any new issue of this document invalidates previous

issues. Micronas reserves the right to review this docu-

ment and to make changes to the document’s content

at any time without obligation to notify any person or

entity of such revision or changes. For further advice

please contact us directly.

Do not use our products in life-supporting systems,

military, aviation, or aerospace applications! Unless

explicitly agreed to otherwise in writing between the

parties, Micronas’ products are not designed, intended

or authorized for use as components in systems

intended for surgical implants into the body, or other

applications intended to support or sustain life, or for

any other application in which the failure of the product

could create a situation where personal injury or death

could occur.

No part of this publication may be reproduced, photo-

copied, stored on a retrieval system or transmitted

without the express written consent of Micronas.

Micronas Trademarks

–HAL

Micronas Patents

Sensor programming with VDD-Modulation protected

by Micronas Patent No. EP 0 953 848.

Third-Party Trademarks

All other brand and product names or company names

may be trademarks of their respective companies.

Contents
Page Section Title
Micronas July 3, 2013; DSH000158_003EN 3
DATA SHEET HAL 1820
1. Introduction
1.1. Major Applications
2.Features
1.3. Marking Code
1.4. Operating Junction Temperature Range (TJ)
1.5. Hall Sensor Package Codes
1.6. Solderability and Welding
1.7. Pin Connections and Short Descriptions
2. Functional Description
2.1. General Function
2.2. Digital Signal Processing and EEPROM
2.2.1. Customer Register I
2.2.2. Customer Register II
2.2.3. Customer register III and IV
2.2.4. Signal Path
2.3. Calibration Procedure
2.3.1. General Procedure
3. Specifications
3.1. Outline Dimensions
3.2. Dimensions of Sensitive Area
3.3. Package Dimensions
3.4. Absolute Maximum Ratings
3.4.1. Storage and Shelf Life
3.5. Recommended Operating Conditions
3.6. Characteristics
3.7. Magnetic Characteristics
3.7.1. Definition of Sensitivity Error ES
4. Application Notes
4.1. Ambient Temperature
4.2. EMC and ESD
4.3. Application Circuit
4.4. Temperature Compensation
5. Programming of the Sensor
5.1. Programming Interface
5.2. Programming Environment and Tools
5.3. Programming Information
6. Data Sheet History

HAL 1820 DATA SHEET

4July 3, 2013; DSH000158_003EN Micronas

Programmable Linear Hall-Effect Sensor

Release Note: Revision bars indicate significant

changes to the previous edition.

1. Introduction

The HAL1820 is a new member of the Micronas family

of programmable linear Hall-Effect Sensors.

The HAL1820 is a universal magnetic field sensor with

a ratiometric, linear analog output. It is produced in

CMOS technology and can be used for magnetic field

measurements, current measurements, and detection

of mechanical movement. Very accurate angle mea-

surements or distance measurements can also be

made. The sensor is very robust and can be used in

electrically and mechanically harsh environments.

Major characteristics like magnetic field range, sensi-

tivity, offset (output voltage at zero magnetic field) and

the temperature coefficients are programmable in a

non-volatile memory. The HAL1820 features a cus-

tomer data register that enables the customer to store

production information (like production serial number)

inside each sensor.

The sensor includes a temperature-compensated Hall

plate with choppered offset compensation, an A/D con-

verter, digital signal processing, an EEPROM memory

with redundancy and lock function for the calibration

data, a serial interface for programming the EEPROM,

a ratiometric linear output and protection devices.

Internal digital signal processing compensates for ana-

log offsets, temperature changes, and mechanical

stress, resulting in highly stable performance.

The HAL1820 is programmable by modulation of the

supply voltage. No additional programming pin is

needed. The easy programmability allows a 2-point

calibration by adjusting the output signal directly to the

input signal (like mechanical angle, distance, or cur-

rent). Individual adjustment of each sensor during the

customer’s manufacturing process is possible. With

this calibration procedure, the tolerances of the sensor,

the magnet and the mechanical positioning can be

compensated in the final assembly.

In addition, the temperature compensation of the Hall

IC can be fit to all common magnetic materials by pro-

gramming first and second order temperature coeffi-

cients of the Hall sensor sensitivity. This enables oper-

ation over the full temperature range with high

accuracy.

The calculation of the individual sensor characteristics

and the programming of the EEPROM memory can

easily be done with a PC and the application kit from

Micronas.

The sensor is designed for industrial and automotive

applications and operates in the junction temperature

range from –40 °C up to 170 °C. The HAL1820 is

available in the very small leaded packages TO92UA-1

and TO92UA-2 and in the SMD-package SOT89B-1.

1.1. Major Applications

Due to the sensor’s robust characteristics, the

HAL1820 is the optimal system solution for applica-

tions such as:

– linear position measurements,

– angle sensors,

– distance measurements,

– magnetic field and current measurement.

1.2. Features

– Ratiometric linear output proportional to the mag-

netic field

– Various programmable magnetic characteristics with

non-volatile memory

– Digital signal processing

– Continuos measurement ranges from  20 mT to

160 mT

– Customer readable Micronas production information

(like lot number, wafer number, etc.)

– Temperature characteristics programmable for

matching all common magnetic materials

– Programming via supply voltage modulation

– Lock function and built-in redundancy for EEPROM

memory

– Temperature and stress-stable quiescent output

voltage

– on-chip temperature compensation

– active offset compensation

– operates from 40 °C up to 170 °C

junction temperature

– operates from 4.5 V up to 5.5 V supply voltage in

specification

– operates with static magnetic fields and dynamic

magnetic fields up to 2.25 kHz

– overvoltage and reverse-voltage protection at VDD

– magnetic characteristics extremely robust against

mechanical stress

– short-circuit protected push-pull output

– EMC and ESD optimized design

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 5

1.3. Marking Code

The HAL1820 has a marking on the package surface

(branded side). This marking includes the name of the

sensor and the temperature range.

1.4. Operating Junction Temperature Range (TJ)

The Hall sensors from Micronas are specified to the

chip temperature (junction temperature TJ).

A: TJ = 40 °C to +170 °C

The relationship between ambient temperature (TA)

and junction temperature is explained in Section 4.1.

on page 22.

1.5. Hall Sensor Package Codes

Hall sensors are available in a wide variety of packag-

ing versions and quantities. For more detailed informa-

tion, please refer to the brochure: “Hall Sensors:

Ordering Codes, Packaging, Handling”.

1.6. Solderability and Welding

Soldering

During soldering reflow processing and manual

reworking, a component body temperature of 260 °C

should not be exceeded.

Welding

Device terminals should be compatible with laser and

resistance welding. Please note that the success of

the welding process is subject to different welding

parameters which will vary according to the welding

technique used. A very close control of the welding

parameters is absolutely necessary in order to reach

satisfying results. Micronas, therefore, does not give

any implied or express warranty as to the ability to

weld the component.

1.7. Pin Connections and Short Descriptions

Fig. 1–1: Pin configuration

Type Temperature Range

HAL 1820 1820A

HALXXXPA-T

Temperature Range: A

Package: SF for SOT89B-1

UA for TO92UA-1/2

Type: 1820

Example: HAL1820UA-A

Type: 1820

Package: TO92UA-1/2

Temperature Range: TJ = 40 C to +170 C

Pin No. Pin Name Short Description

SUP Supply Voltage and Pro-

gramming Pin

2 GND Ground

3 OUT Push-Pull Output in

Application mode

4 GND Ground

2,4

VDD

OUT

GND

HAL 1820 DATA SHEET

6July 3, 2013; DSH000158_003EN Micronas

2. Functional Description

2.1. General Function

The HAL1820 is a monolithic integrated circuit which

provides an output voltage proportional to the mag-

netic flux through the Hall plate and proportional to the

supply voltage (ratiometric behavior).

The external magnetic field component perpendicular

to the branded side of the package generates a Hall

voltage. The Hall IC is sensitive to magnetic north and

south polarity. This voltage is converted to a digital

value, processed in the Digital Signal Processing Unit

(DSP) according to the settings of the EEPROM regis-

ters, converted back to an analog voltage by a D/A

converter and buffered by a push-pull output transistor

stage. The function and the parameter for the DSP are

explained in Section 2.2. on page 8. Internal tempera-

ture compensation circuitry and the choppered offset

compensation enables operation over the full tempera-

ture range with minimal degradation in accuracy and

offset. The circuitry also rejects offset shifts due to

mechanical stress from the package. In addition, the

sensor IC is equipped with devices for overvoltage and

reverse-voltage protection at supply pin.

A LOCK register disables the programming of the

EEPROM memory. The register can not be reset by

the customer.

As long as the LOCK register is not set, the output

characteristic can be adjusted by programming the

EEPROM registers. The IC can be programmed via

VSUP line. After detecting a command, the sensor

reads or writes the memory and answers with a digital

signal on the output pin.

Output/Magnetic Field Polarity

Applying a south-pole magnetic field perpendicular to

the branded side of the package will increase the out-

put voltage (for Sensitivity < 0) from the quiescent (off-

set) voltage towards the supply voltage. A negative

magnetic field will decrease the output voltage. The

output logic will be inverted for sensitivity >0.

In addition HAL1820 features an internal error detec-

tion. The following error modes can be detected:

– Over-/underflow in adder or multiplier

– Over-/underflow in A/D converter

– Overtemperature detection

In case of an error the sensors output will be forced to

the lower error band. The error band is defined by

VDIAG (see Section 3.6. on page 14).

Fig. 2–1: HAL1820 block diagram

Internally

Temperature

Oscillator

Switched Digital D/A Analog

GND

EEPROM Memory

Lock Control

stabilized

Supply and

Protection

Devices

Dependent

Bias

Protection

Devices

Hall Plate Signal

Processing Converter Output

A/D

Converter

Undervoltage

Detection

OUT

VSUP

Programming

Interface

50 

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 7

Fig. 2–2: Details of Programming Parameter and Digital Signal Processing

Table 2–1: Cross reference table EEPROM register and sensor parameter

EEPROM-Register Parameter Data Bits Function

customer register I Sensitivity 8 Magnetic sensitivity

Offset 8 Magnetic offset

customer register II LOCKR 1 Customer Lock

OALN 1 Magnetic Offset Alignment Bit (MSB or LSB aligned)

TCSQ 5 Quadratic temperature coefficient

TC 5 Linear temperature coefficient

MRANGE 3 Available magnetic ranges

customer register III Micronas

Data

16 Micronas production information (read only)

customer register IV Micronas

Data

16 Micronas production information (read only)

5 bit

TCSQ

5 bit

Offset

8 bit

1 bit

Micronas

MRange

3 bit

Lock

Programming Parameter

A/D

Converter

Multiplier

Adder Output

Digital Signal Processing

Digital Output Register

10 bit

Lock

Control

Sensitivity

8 bit

OALN

1 bit

HAL 1820 DATA SHEET

8July 3, 2013; DSH000158_003EN Micronas

2.2. Digital Signal Processing and EEPROM

The DSP is the major part of this sensor and performs

the signal conditioning. The parameters for the DSP

are stored in the EEPROM registers. The details are

shown in Fig. 2–2.

The measurement data can be readout from the

DIGITAL OUTPUT register.

DIGITAL OUTPUT

This 16-bit register delivers the actual digital value of

the applied magnetic field after the signal processing.

This register can only be read out, and it is the basis

for the calibration procedure of the sensor in the sys-

tem environment. Only 10 bits of the register contain

valid data. The DIGITAL OUTPUT range is from 512

to 511.

For Sensitivity = 1 the DIGITAL OUTPUT value will

increase for negative magnetic fields (north pole) on

the branded side of the package (positive DIGITAL

OUTPUT values).

Note: During application design, it should be taken

into consideration that DIGITAL OUTPUT

should not saturate in the operational range of

the specific application.

The area in the EEPROM accessible for the customer

consists of four so called customer registers with a size

of 16 bit each.

2.2.1. Customer Register I

Customer register I contains the bits for magnetic sen-

sitivity (SENSITIVITY) and magnetic offset (OFFSET).

SENSITIVITY

The SENSITIVITY bits define the parameter for the

multiplier in the DSP. The Sensitivity is programmable

between 2 and 2. The SENSITIVITY bits can be

changed in steps of 0.0156. Sensitivity = 1 (@ Offset =

0) corresponds to full-scale of the output signal if the

A/D-converter value has reached the full-scale value.

OFFSET

The OFFSET bits define the parameter for the adder in

the DSP. Offset defines the output signal without exter-

nal magnetic field (B = 0 mT).

The customer can decide if the Offset is MSB aligned

or LSB aligned. The MSB or LSB alignment is enabled

by an additional Offset alignment bit (OALN). In case

the OALN bit is 1 the Offset is programmable from

50% up to 50% of VDD. This means that the Offset

covers the full-scale range. If the OALN bit is set to

zero, then the Offset covers only 1/4 of the full-scale

(12.5% up to 12.5% of VDD). The customer can

adjust the Offset symmetrically around 50% of VDD

(37.5%... 62.5% of VDD). The OFFSET register can be

set with 8-bit resolution.

2.2.2. Customer Register II

Customer register II contains the bits for magnetic

range (MRANGE), linear and quadratic temperature

coefficients (TC and TCSQ), magnetic offset alignment

(OALN) and the customer lock bit.

MRANGE

The MRANGE bits define the magnetic field range of

the A/D converter. The following eight magnetic ranges

are available.

Table 2–2: MRANGE bit definition

Magnetic Field Range BIT SETTING

20 mT...20 mT 0

40 mT...40 mT 1

60 mT...60 mT 2

80 mT...80 mT 3

100 mT...100 mT 4

120 mT...120 mT 5

140 mT...140 mT 6

160 mT...160 mT 7

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 9

TC and TCSQ

The temperature dependence of the magnetic sensitiv-

ity can be adapted to different magnetic materials in

order to compensate for the change of the magnetic

strength with temperature. The adaption is done by

programming the TC (Linear Temperature Coefficient)

and the TCSQ registers (Quadratic Temperature Coef-

ficient). Thereby, the slope and the curvature of the

temperature dependence of the magnetic sensitivity

can be matched to the magnet and the sensor assem-

bly. As a result, the output signal characteristic can be

fixed over the full temperature range. The sensor can

compensate for linear temperature coefficients ranging

from about 3100 ppm/K up to 2550 ppm/K and qua-

dratic coefficients from about 7 ppm/K2 to 15 ppm/K2

(typical range). Min. and max. values for quadratic

temperature coefficient depend on linear temperature

coefficient. Please refer to Section 4.4. on page 22 for

the recommended settings for different linear tempera-

ture coefficients.

Magnetic Offset Alignment Bit (OALN)

Please refer to Section 2.2.1. on page 8 (OFFSET).

LOCK

By setting this 1-bit register, all registers will be locked,

and the EEPROM content can not be changed any-

more. It is still possible to read all register content by

sending a read command to the sensor. The LOCK bit

is active after the first power-off and power-on

sequence after setting the LOCK bit.

Warning: This register cannot be reset!

2.2.3. Customer register III and IV

Customer register III and IV contain 16 bits each.

These two registers can be read by the customer and

Micronas will use this register to store production infor-

mation like wafer position, wafer number and produc-

tion lot number.

HAL 1820 DATA SHEET

10 July 3, 2013; DSH000158_003EN Micronas

Fig. 2–3: Signal path HAL1820

2.2.4. Signal Path

Fig. 2–3 shows the signal path and signal processing

of HAL1820. The measurement output value y is cal-

culated out of the input signal X with the following

equation

The parameters offset and sensitivity are two’s com-

plement encoded 8-bit values (see Section 2.2.1. on

page 8).

2.3. Calibration Procedure

2.3.1. General Procedure

For calibration in the system environment, the applica-

tion kit from Micronas is recommended. It contains the

hardware for the generation of the serial telegram for

programming and the corresponding software for the

input of the register values.

For the individual calibration of each sensor in the cus-

tomer application, a two-point adjustment is recom-

mended. Please use Micronas Software Kit for the cal-

ibration.

Locking the Sensor

The last step is activating the LOCK function by setting

the LOCK bit. Please note that the LOCK function

becomes effective after power-down and power-up of

the Hall IC. The sensors EEPROM is then locked and

its content can not be changed anymore. The sensor

still answers to read commands on the supply line.

Warning: This register cannot be reset!

ADC

+FS

FS

FS range

}

±1

±0.5 (OALN = 0)

±0.125 (OALN = 1)

8-bit offset value (128...+127)

±2

8-bit sensitivity value (128...+127)

10-bit readout-value (512...+511)

±1 @ offset = 0 and sensitivity = 1

Definition: FS of ADC = 1.

{

clamp

y/n

ADC value adder out

range ±7936 range 8192/8191

range

+range

Y sensitivity X OFFSET–=

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 11

3. Specifications

3.1. Outline Dimensions

Fig. 3–1:

SOT89B-1: Plastic Small Outline Transistor package, 4 leads

Ordering code: SF

Weight approximately 0.034 g

HAL 1820 DATA SHEET

12 July 3, 2013; DSH000158_003EN Micronas

Fig. 3–2:

TO92UA-1: Plastic Transistor Standard UA package, 3 leads, spread

Weight approximately 0.106 g

ISSUE DATE

YY-MM-DD

ITEM NO.

solderability is guaranteed between end of pin and distance F1.

A4, y= these dimensions are different for each sensor type and is specified in the data sheet.

mm 1.55

1.45 0.7

JEDEC STANDARD

ISSUE

UNIT A2 A3

0.2 0.36 3.05 4.11

4.01

2.540.42

ANSI

- 09-06-09

Bdbc

D1 e E1

5 mm

4.0

2.0

45°

15.5

min

15.0

min

1.2

0.8

0.60

0.42

06616.0001.4

DRAWING-NO.

ZG001016_Ver.06

ZG-NO.

LF1 F2 F3

scale

2.5

1 2

Center of sensitive area

physical dimensions do not include moldflash.

min/max of D1 are specified in the datasheet.

Sn-thickness might be reduced by mechanical handling.

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 13

Fig. 3–3:

TO92UA-2: Plastic Transistor Standard UA package, 3 leads, not spread

Weight approximately 0.106 g

DRAWING-NO.

06612.0001.4

15.5

min

A4, y= these dimensions are different for each sensor type and is specified in the data sheet.

1.55

1.45

JEDEC STANDARD

ISSUE

mm 0.7

ITEM NO.

0.42 0.2

solderability is guaranteed between end of pin and distance F1.

UNIT A3 bBd

3.05 4.11

4.01

1.2

0.8

0.60

0.42

ISSUE DATE

YY-MM-DD

09-06-05

ANSI

0.36 1.27

cD1 e

F1 F2 L

ZG-NO.

ZG001012_Ver.07

45°

2.5

scale

5 mm

123

Center of sensitive area

physical dimensions do not include moldflash.

min/max of D1 are specified in the datasheet.

Sn-thickness might be reduced by mechanical handling.

HAL 1820 DATA SHEET

14 July 3, 2013; DSH000158_003EN Micronas

Fig. 3–4:

TO92UA/UT-1: Dimensions ammopack inline, spread

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 15

Fig. 3–5:

TO92UA/UT-2: Dimensions ammopack inline, not spread

HAL 1820 DATA SHEET

16 July 3, 2013; DSH000158_003EN Micronas

3.2. Dimensions of Sensitive Area

0.2 mm x 0.1 mm

3.3. Package Dimensions

3.4. Absolute Maximum Ratings

Stresses beyond those listed in the “Absolute Maximum Ratings” may cause permanent damage to the device. This

is a stress rating only. Functional operation of the device at these conditions is not implied. Exposure to absolute

maximum rating conditions for extended periods will affect device reliability.

This device contains circuitry to protect the inputs and outputs against damage due to high static voltages or electric

fields; however, it is advised that normal precautions be taken to avoid application of any voltage higher than abso-

lute maximum-rated voltages to this circuit.

All voltages listed are referenced to ground (GND).

TO92UA-1/-2 SOT89B-1

y 1.0 mm nominal 0.95 mm nominal

A4 0.4 mm nominal 0.4 mm nominal

D1 3.05  0.05 mm 2.55  0.05 mm

H1 min. 21 mm

max. 23.1 mm

not applicable

Symbol Parameter Pin No. Min. Max. Unit Condition

VSUP Supply Voltage 1 8.5

14.4

15

8.5

14.4

Vt < 96 h

t < 10 min.

t < 1 min.

not additive

VOUT Output Voltage 3 0.51)

0.51)

8.5

14.4

Vt < 96 h

t < 10 min.

t < 1 min.

not additive

VOUTVSUP Excess of Output Voltage

over Supply Voltage

1,3 0.5 V

IOUT Continuous Output Current 3 55mA

tSh Output Short Circuit Duration 3 10 min

TJJunction Temperature under

Bias

40 190 °C 2)

VESD ESD Protection3) 1,2,3 4.0 4.0 kV

1) internal protection resistor = 50 

2) for 96h - Please contact Micronas for other temperature requirements

3) AEC-Q100-002 (100 pF and 1.5 k

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 17

3.4.1. Storage and Shelf Life

The permissible storage time (shelf life) of the sensors is unlimited, provided the sensors are stored at a maximum of

30 °C and a maximum of 85% relative humidity. At these conditions, no Dry Pack is required.

Solderability is guaranteed for one year from the date code on the package.

3.5. Recommended Operating Conditions

Functional operation of the device beyond those indicated in the “Recommended Operating Conditions/Characteris-

tics” is not implied and may result in unpredictable behavior of the device and may reduce reliability and lifetime.

All voltages listed are referenced to ground (GND).

Symbol Parameter Pin No. Min. Typ. Max. Unit Remarks

VSUP Supply Voltage 1 4.5

5.7

5.85

5.5

6.0

V Normal operation

During programming

IOUT Continuous Output Current 3 11mA

RLLoad Resistor 3 5.5 10 k

CLLoad Capacitance 3 0.33 10 47 nF

NPRG Number of EEPROM

Programming Cycles

100 0 °C < Tamb < 55 °C

TJJunction Operating

Temperature1) 40

40



125

150

170

°C

for 8000 hrs

for 2000 hrs

for 1000 hrs

Time values are not addi-

tive.

1) Depends on the temperature profile of the application. Please contact Micronas for life time calculations.

HAL 1820 DATA SHEET

18 July 3, 2013; DSH000158_003EN Micronas

3.6. Characteristics

at TJ = 40 °C to +170 °C (for temperature type A), VSUP = 4.5 V to 5.5 V, GND = 0 V, after programming the sensor

and locking the EEPROM,

at Recommended Operation Conditions if not otherwise specified in the column “Conditions”.

Typical Characteristics for TJ = 25 °C and VSUP = 5 V.

Symbol Parameter Pin No. Min. Typ. Max. Unit Conditions

ISUP Supply Current

over Temperature Range

1710mA

Resolution 3 10 Bit

INL Non-Linearity of Output

Voltage over Temperature

31.0 0 1.0 % % of supply voltage1)

ERRatiometric Error of Output

over Temperature

(Error in VOUT / VSUP)

31.0 0 1.0 %

VOUTH Output High Voltage 3 4.7 4.9 V V

SUP = 5 V, IOUT = +/ 1 mA2)

VOUTL Output Low Voltage 3 0.1 0.3 V VSUP = 5 V, IOUT = +/ 1 mA2)

tr(O) Response Time of Output3) 30.5 1 ms CL = 10 nF, time from 10% to

90% of final output voltage for a

step like

signal Bstep from 0 mT to Bmax

tPOD Power-Up Time (Time to

reach stabilized Output

Voltage)3)

11.5msC

L = 10 nF, 90% of VOUT

BW Small Signal Bandwidth (

3dB)

3) 3 2.25 2.5 kHz BAC < 10 mT

VOUTn Output RMS Noise3) 32.6 5 mV B = 5% to 95% of Bmax

ROUT Output Resistance over

Recommended Operating

Range3)

360 VOUTLmax VOUT VOUTHmin

VPORLH Power-On Reset Level from

VSUPLow to VSUPHigh

1 3.9 4.35 4.5 V

VPORHL Power-On Reset Level from

VSUPHighto VSUPLow

13.84.24.4V

VPORHYS Power-On Reset Hysteresis 1 0.1 0.175 0.3 V

VDIAG Output Voltage in case of

Error Detection

30300 mV

TO92UA Package

Rthja

Rthjc

Thermal Resistance

junction to air

junction to case



250

K/W

Measured with a 1s0p board

SOT89B Package

Rthja

Rthjc

Thermal Resistance

junction to air

junction to case



210

K/W

Measured with a 1s0p board

30 mm x 10 mm x 1.5 mm,

pad size (see Fig. 3–6)

1)If more than 50% of the selected magnetic field range are used and VOUT is between 0.3 V and 4.7 V

2) Linear output range

3) Guaranteed by design

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 19

Fig. 3–6: Recommended footprint SOT89B-1, Dimensions in mm.

All dimensions are for reference only. The pad size may vary depending on the requirements of the soldering

process.

3.7. Magnetic Characteristics

at Recommended Operating Conditions if not otherwise specified in the column ’Test Conditions’,

TJ =40 °C to +170 °C (for temperature type A), VSUP = 4.5 V to 5.5 V, after programming the sensor and locking the

EEPROM.

Typical Characteristics for TA = 25 °C and VSUP = 5 V.

1.05

1.80

0.50

1.50

1.45

2.90

Symbol Parameter Pin No. Values Unit Test Conditions

Min. Typ. Max.

RANGEABS Absolute Magnetic Range

of A/D Converter over

temperature

80 100 120 % % of nominal RANGE

Nominal RANGE pro-

grammable from

20 mT up to 160 mT

RANGE Magnetic field range  20

 40

 80  160

 160

mT TO92UA-1/-2

SOT89B-1

Sensitivity Trim range for absolute

sensitivity1) 310 110mV/

Depending on mag-

netic field range 1) and

SENS register content

Senstrim Trim step for absolute

sensitivity1) 30.3

mV/

At min. sensitivity

At max. sensitivity

Offsettrim Offset trim1) 32.5

10

312

1250

mV OALN=0

OALN=1

ES Sensitivity Error over Tem-

perature Range

36 0 6 % Part to part variation

for certain combina-

tions of TC and TCSQ

(see Section 3.7.1.)

HAL 1820 DATA SHEET

20 July 3, 2013; DSH000158_003EN Micronas

Fig. 3–7: Definition of Sensitivity Error ES.

SensLife Sensitivity Drift (beside

temperature drift)1)

2%T

J = 25 °C; after tem-

perature cycling and

over life time

BOFFSET Magnetic offset 3 20 2 mTB = 0 mT, T

A = 25 °C

BOFFSET Magnetic offset drift over

Temperature Range

BOFFSET(T)  BOFFSET

(25 °C)

3300 0 300 µT B = 0 mT, RANGE =

20 mT, Sens = 100

mV/mT

BHysteresis Magnetic Hysteresis1) 320 0 20 µT Range = 40 mT

1) Guaranteed by design

Symbol Parameter Pin No. Values Unit Test Conditions

Min. Typ. Max.

50 75 100 125 150 175

-25

-50

0.98

0.99

1.00

1.01

1.02

1.03

-10

0.993

1.001

temperature [°C]

relative sensitivity related to 25 °C value

ideal 200 ppm/k

least-square-fit straight-line of

normalized measured data

measurement example of real

sensor, normalized to achieve a

value of 1 of its least-square-fit

straight-line at 25 °C

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 21

3.7.1. Definition of Sensitivity Error ES

ES is the maximum of the absolute value of 1 minus

the quotient of the normalized measured value1) over

the normalized ideal linear2) value:

In the example shown in Fig. 3–7 the maximum error

occurs at 10 °C:

1) normalized to achieve a least-square-fit straight-line

that has a value of 1 at 25 °C

2) normalized to achieve a value of 1 at 25 °C

ES max abs meas

ideal

------------1–









Tmin, Tmax

ES 1.001

0.993

------------- 1–0.8%==

HAL 1820 DATA SHEET

22 July 3, 2013; DSH000158_003EN Micronas

4. Application Notes

4.1. Ambient Temperature

Due to the internal power dissipation, the temperature

on the silicon chip (junction temperature TJ) is higher

than the temperature outside the package (ambient

temperature TA).

TJ = TA + T

At static conditions and continuous operation, the fol-

lowing equation applies:

T = ISUP * VSUP * RthjX

The X represents junction to air or to case.

For worst case calculation, use the max. parameters

for ISUP and RthjX, and the max. value for VSUP from

the application.

The following example shows the result for junction to

air conditions. VSUP = 5.5 V, Rthja = 250 K/W and ISUP

= 10 mA the temperature difference T = 13.75 K.

The junction temperature TJ is specified. The maxi-

mum ambient temperature TAmax can be calculated as:

TAmax = TJmax T

4.2. EMC and ESD

The HAL1820 is designed for a stabilized 5 V supply.

Interferences and disturbances conducted along the

12 V onboard system (product standard ISO 7637 part

1) are not relevant for these applications.

For applications with disturbances by capacitive or

inductive coupling on the supply line or radiated distur-

bances, the application circuit shown in Fig. 4–1 is rec-

ommended. Applications with this arrangement should

pass the EMC tests according to the product stan-

dards ISO 7637 part 3 (Electrical transient transmis-

sion by capacitive or inductive coupling) and part 4

(Radiated disturbances).

4.3. Application Circuit

For EMC protection, it is recommended to connect one

ceramic 47 nF capacitor between ground and output

voltage pin as well as 100 nF between supply and

ground.

Fig. 4–1: Recommended application circuit

4.4. 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.

Note: Micronas recommends to use the HAL1820

Programming Environment to find optimal set-

tings for temperature coefficients. Please con-

tact Micronas for more detailed information.

Temperature Coefficient

of Magnet (ppm/K)

TC TCSQ

2100 8 0

1800 10 3

1500 12 4

1200 14 5

900 16 6

500 18 6

150 20 6

0215

300 22 5

500 23 4

750 24 4

1000 25 2

1500 27 0

2100 29 5

2700 31 5

OUT

VSUP

GND

100 nF HAL1820

47 nF

DATA SHEET HAL 1820

Micronas July 3, 2013; DSH000158_003EN 23

5. Programming of the Sensor

HAL1820 features two different customer modes. In

Application Mode the sensor provides a ratiometric

analog output voltage. In Programming Mode it is

possible to change the register settings of the sensor.

After power-up the sensor is always operating in the

Programming Mode (default after delivery from

Micronas and as long as the sensor is not locked). It is

switched to the Application Mode by setting a certain

volatile bit in the memory of the sensor or by locking

the sensor.

5.1. Programming Interface

In Programming Mode the sensor is addressed by

modulating a serial telegram on the sensors supply

voltage. The sensor answers with a modulation of the

output voltage.

A logical “0” is coded as no level change within the bit

time. A logical “1” is coded as a level change of typi-

cally 50% of the bit time. After each bit, a level change

occurs (see Fig. 5–1).

The serial telegram is used to transmit the EEPROM

content, error codes and digital values of the magnetic

field from and to the sensor.

Fig. 5–1: Definition of logical 0 and 1 bit

A description of the communication protocol and the

programming of the sensor is available in a separate

document (Application Note Programming HAL1820).

trtf

tp0 tp0

logical 0

VDDH

VDDL

tp0

logical 1

VDDH

VDDL

or tp0

tp1

Table 5–1: Telegram parameters (All voltages are referenced to GND.)

Symbol Parameter Pin No. Limit Values Unit Test Conditions

Min. Typ. Max.

VSUPL Supply Voltage for Low Level

during Programming through

Sensor VSUP Pin

1 5.8 6.3 6.6 V

VSUPH Supply Voltage for High Level

during Programming through

Sensor VSUP Pin

1 6.8 7.3 7.8 V

VSUPProgram VSUP Voltage for EEPROM

programming (after PROG and

ERASE)

1 5.7 5.85 6.0 V

tp0 Bit time if command send to the

sensor

11024 µs

tpOUT Bit time for sensor answer 3 1024 µs

HAL 1820 DATA SHEET

24 July 3, 2013; DSH000158_003EN Micronas

5.2. Programming Environment and Tools

For the programming of HAL1820 during product

development and also for production purposes a pro-

gramming tool including hardware and software is

available on request. It is recommended to use the

Micronas tool kit in order to easy the product develop-

ment. The details of programming sequences are also

available on request.

5.3. Programming Information

For production and qualification tests, it is mandatory

to set the LOCK bit after final adjustment and program-

ming of HAL1820. The LOCK function is active after

the next power-up of the sensor.

The success of the LOCK process should be checked

by reading the status of the LOCK bit after locking and/

or by an analog check of the sensors output signal.

HAL1820 features a diagnostic register to check the

success and quality of the programming process. It is

mandatory to check that all bits of the DIAGN register

are 0 after the programming of the sensor. More

details can be found in the application note “HAL1820

Programming Guide”.

Electrostatic Discharges (ESD) may disturb the pro-

gramming pulses. Please take precautions against

ESD.

HAL 1820 DATA SHEET

25 July 3, 2013; DSH000158_003EN Micronas

Micronas GmbH

Hans-Bunte-Strasse 19  D-79108 Freiburg  P.O. Box 840  D-79008 Freiburg, Germany

Tel. +49-761-517-0  Fax +49-761-517-2174  E-mail: docservice@micronas.com  Internet: www.micronas.com

6. Data Sheet History

1. Advance Information: “HAL 1820, Programmable

Linear Hall-Effect Sensor”, June 30, 2009,

AI000149_001EN. First release of the advance

information.

2. Advance Information: “HAL 1820, Programmable

Linear Hall-Effect Sensor”, April 28, 2010,

AI000149_002. Second release of the advance

information.

Major Changes:

– Reset levels added

– TC/TCSQ table added

– Update of magnetic parameters

3. Data Sheet: “HAL 1820 Programmable Linear Hall-

Effect Sensor”, April 28, 2011, DSH000158_001EN.

First release of the data sheet.

4. Data Sheet: “HAL 1820 Programmable Linear Hall-

Effect Sensor”, April 23, 2013, DSH000158_002EN.

Second release of the data sheet.

Major Changes:

– Temperature range “K” removed

5. Data Sheet: “HAL 1820 Programmable Linear Hall-

Effect Sensor”, July 3, 2013, DSH000158_003EN.

Third release of the data sheet.

Major Changes:

– Section 3.7. Magnetic Characteristics