TLE4941C - Infineon Technologies - Datasheet.Directory

Data Sheet, V2.1, February 2005

Differential Two-Wire Hall Effect

Sensor-IC for Wheel Speed Applications

TLE4941

TLE4941C

Sensors

Never stop thinking.

Edition 2004-03-19

Published by Infineon Technologies AG,

St.-Martin-Strasse 53,

81669 München, Germany

Attention please!

The information herein is given to describe certain components and shall not be considered as a guarantee of

characteristics.

Terms of delivery and rights to technical change reserved.

We hereby disclaim any and all warranties, including but not limited to warranties of non-infringement, regarding

circuits, descriptions and charts stated herein.

Information

For further information on technology, delivery terms and conditions and prices please contact your nearest

Infineon Technologies Office (www.infineon.com).

Warnings

Due to technical requirements components may contain dangerous substances. For information on the types in

question please contact your nearest Infineon Technologies Office.

Infineon Technologies Components may only be used in life-support devices or systems with the express written

approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure

of that life-support device or system, or to affect the safety or effectiveness of that device or system. Life support

devices or systems are intended to be implanted in the human body, or to support and/or maintain and sustain

and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may

be endangered.

PG-SSO-2-1

PG-SSO-2-2

Data Sheet 3 V2.1, 2005-02

Differential Two-Wire Hall Effect Sensor IC TLE4941

TLE4941C

Features

• Two-wire current interface

• Dynamic self-calibration principle

• Single chip solution

• No external components needed

• High sensitivity

• South and north pole pre-induction possible

• High resistance to piezo effects

• Large operating air-gaps

• Wide operating temperature range

• TLE4941C: 1.8 nF overmolded capacitor

The Hall Effect sensor IC TLE4941 is designed to provide information about rotational

speed to modern vehicle dynamics control systems and ABS. The output has been

designed as a two wire current interface. The sensor operates without external

components and combines a fast power-up time with a low cut-off frequency. Excellent

accuracy and sensitivity is specified for harsh automotive requirements as a wide

temperature range, high ESD and EMC robustness. State-of-the art BiCMOS technology

is used for monolithic integration of the active sensor areas and the signal conditioning

circuitry.

Finally, the optimized piezo compensation and the integrated dynamic offset

compensation enable easy manufacturing and elimination of magnet offsets.

The TLE4941C is additionally provided with an overmolded 1.8 nF capacitor for

improved EMI performance.

Type Marking Ordering Code Package

TLE4941 4100R Q62705-K714 PG-SSO-2-1

TLE4941C 41C0R Q62705-K715 PG-SSO-2-2

TLE4941 Series

TLE4941

TLE4941C

Data Sheet 4 V2.1, 2005-02

Pin Configuration

(view on branded side of component)

Figure 1

Figure 2 Block Diagram

AEP0320

Center of

sensitive are

VGND

0015

4100R

Data Code

Marking

2.67

2.5

1.44

B B

A0.3

VGND

AEB0320

PGA Speed

ADC

Oscillator

(syst clock)

Main

Comp

Gain Range

Offset

DAC

"GND

Digital

Circuit

Power Supply

Regulator

all

robes

TLE4941

TLE4941C

Data Sheet 5 V2.1, 2005-02

Functional Description

The differential hall sensor IC detects the motion of ferromagnetic and permanent

magnet structures by measuring the differential flux density of the magnetic field. To

detect the motion of ferromagnetic objects the magnetic field must be provided by a back

biasing permanent magnet. Either south or north pole of the magnet can be attached to

the rear unmarked side of the IC package.

Magnetic offsets of up to ± 20 mT and device offsets are cancelled by a self-calibration

algorithm. Only a few transitions are necessary for self-calibration. After the initial

calibration sequence switching occurs when the input signal is crossing the arithmetic

mean of its max. and min. value (e.g. zero-crossing for sinusoidal signals).

The ON and OFF state of the IC are indicated by High and Low current consumption.

Circuit Description

The circuit is supplied internally by a 3 V voltage regulator. An on-chip oscillator serves

as clock generator for the digital part of the circuit.

TLE4941 signal path is comprised of a pair of hall probes, spaced at 2.5 mm, a

differential amplifier including a noise-limiting low-pass filter and a comparator feeding a

switched current output stage. In addition an offset cancellation feedback loop is

provided by a signal-tracking A/D converter, a digital signal processor (DSP) and an

offset cancellation D/A converter.

During the startup phase (un-calibrated mode) the output is disabled (I = ILOW).

The differential input signal is digitized in the speed A/D converter and fed into the DSP.

The minimum and maximum values of the input signal are extracted and their

corresponding arithmetic mean value is calculated. The offset of this mean value is

determined and fed into the offset cancellation DAC.

After successful correction of the offset, the output switching is enabled.

In running mode (calibrated mode) the offset correction algorithm of the DSP is switched

into a low-jitter mode, avoiding oscillation of the offset DAC LSB. Switching occurs at

zero-crossing. It is only affected by the (small) remaining offset of the comparator and by

the remaining propagation delay time of the signal path, mainly determined by the noise-

limiting filter. Signals below a defined threshold ∆BLimit are not detected to avoid

unwanted parasitic switching.

Package Information

Pure tin covering (green lead plating) is used. Leadframe material is Wieland K62 (UNS:

C18090) and contains CuSn1CrNiTi. Product is RoHS (restriction of hazardous

substances) compliant when marked with letter G in front or after the data code marking

and may contain a data matrix code on the rear side of the package (see also information

note 136/03). Please refer to your Key account team or regional sales if you need further

information.

TLE4941

TLE4941C

Data Sheet 6 V2.1, 2005-02

Note: Stresses in excess of those listed here may cause permanent damage to the

device. Exposure to absolute maximum rating conditions for extended periods

may affect device reliability.

Table 1 Absolute Maximum Ratings

Tj = – 40°C to 150°C, 4.5 V ≤ Vcc ≤ 16.5 V

Parameter Symbol Limit Values Unit Remarks

min. max.

Supply voltage VCC – 0.3 – V Tj < 80°C

–16.5 Tj = 170°C

–20 Tj = 150°C

–22 t = 10 × 5 min.

–24 t = 10 × 5 min.,

RM ≥ 75 Ω

included in VCC

–27 t = 400 ms, RM ≥ 75 Ω

included in VCC

Reverse polarity current Irev –200 mA External current

limitation required,

t < 4 h

Junction temperature Tj–150 °C 5000 h, VCC < 16.5 V

–160 2500 h, VCC < 16.5 V

(not additive)

–170 500 h, VCC < 16.5 V

(not additive)

–190 4 h, VCC < 16.5 V

Active lifetime tB,active 10000 – h

Storage temperature TS– 40 150 °C

Thermal resistance

PG-SSO-2-1

RthJA –190 K/W 1)

1) Can be improved significantly by further processing like overmolding

TLE4941

TLE4941C

Data Sheet 7 V2.1, 2005-02

Note: Within the operating range the functions given in the circuit description are fulfilled.

Table 2 ESD Protection

Human Body Model (HBM) tests according to:

Standard EIA/JESD22-A114-B HBM (covers MIL STD 883D)

Parameter Symbol Limit Values Unit Notes

min. max.

ESD-Protection

TLE4941

TLE4941C

VESD

–

± 12

kV R = 1.5 kΩ,

C = 100 pF

Table 3 Operating Range

Parameter Symbol Limit Values Unit Remarks

min. max.

Supply voltage VCC 4.5 20 VDirectly on IC

leads includes

not the RM

voltage drop

Supply voltage ripple VAC –6Vpp VCC = 13 V

0 < f < 50 kHz

Junction temperature Tj– 40 150 °C

–170 500 h,

VCC ≤ 16.5 V,

increased jitter

permissible

Pre-induction B0– 500 + 500 mT

Pre-induction offset

between outer probes

∆Bstat., l/r – 20 + 20 mT

Differential Induction ∆B– 120 + 120 mT

TLE4941

TLE4941C

Data Sheet 8 V2.1, 2005-02

Table 4 Electrical Characteristics

All values specified at constant amplitude and offset of input signal, over

operating range, unless otherwise specified.

Typical values correspond to VCC = 12 V and TA = 25°C

Parameter Symbol Limit Values Unit Remarks

min. typ. max.

Supply current ILOW 5.9 78.4 mA

Supply current IHIGH 11.8 14 16.8 mA

Supply current ratio IHIGH / ILOW 1.9 – –

Output rise/fall slew rate

TLE4941

tr, tf12

7.5

–

mA/µs

RM ≤ 150 Ω

RM ≤ 750 Ω

See Figure 4

Output rise/fall slew rate

TLE4941C

tr, tf

–

mA/µs

RM = 75 Ω

T < 125°C

T < 170°C

See Figure 4

Current ripple dIX/dVCC IX––90 µA/V

Limit threshold

1 Hz < f < 2500 Hz

2500 Hz < f < 10000 Hz

∆BLimit

0.35

–

0.8

–

1.5

1.7

mT 1)

Initial calibration

delay time

td,input ––300 µs Additional to

nstart

Magnetic edges required

for initial calibration 2)

nstart –36 3) magn.

edges

7th edge correct

Frequency f1

2500

–

2500

10000

Hz 5)

Frequency changes df/dt ––± 100

Hz/ms

Duty cycle duty 40 50 60 %6) Measured

@∆B = 2 mT

sine wave Def.

See Figure 4

Jitter, Tj < 150°C

Tj < 170°C

1 Hz < f < 2500 Hz

SJit-close –

–

± 2

± 3

%7) 1σ value

VCC = 12 V

∆B ≥ 2 mT

Jitter, Tj < 150°C

Tj < 170°C

2500 Hz < f < 10000 Hz

SJit-close –

–

± 3

± 4.5

%7) 1σ value

VCC = 12 V

∆B ≥ 2 mT

TLE4941

TLE4941C

Data Sheet 9 V2.1, 2005-02

Jitter, Tj < 150°C

Tj < 170°C

1 Hz < f < 2500 Hz

SJit-far –

–

± 4

± 6

%7) 1σ value

VCC = 12 V

2 mT

≥

∆

Limit

Jitter, Tj < 150°C

Tj < 170°C

2500 Hz < f < 10000 Hz

SJit-far –

–

± 6

± 9

%7) 1σ value

VCC = 12 V

2 mT

≥

∆

Limit

Jitter at board net ripple SJit-AC ––± 2 %

= 13 V ± 6 Vpp

0 < f < 50 kHz

∆B = 15 mT

1) Magnetic amplitude values, sine magnetic field, limits refer to the 50% critera. 50% of edges are missing

2) The sensor requires up to nstart magnetic switching edges for valid speed information after power-up or after a

stand still condition. During that phase the output is disabled.

3) See “Appendix B”

4) One magnetic edge is defined as a montonic signal change of more than 3.3 mT

5) High frequency behavior not subject to production test - verified by design/characterization. Frequency above

2500 Hz may have influence on jitter performance and magnetic thresholds.

6) During fast offset alterations, due to the calibration algorithm, exceeding the specified duty cycle is permitted

for short time periods

7) Not subject to production test verified by design/characterization

Table 4 Electrical Characteristics (cont’d)

All values specified at constant amplitude and offset of input signal, over

operating range, unless otherwise specified.

Typical values correspond to VCC = 12 V and TA = 25°C

Parameter Symbol Limit Values Unit Remarks

min. typ. max.

TLE4941

TLE4941C

Data Sheet 10 V2.1, 2005-02

Output Description

Under ideal conditions, the output shows a duty cycle of 50%. Under real conditions, the

duty cycle is determined by the mechanical dimensions of the target wheel and its

tolerances (40% to 60% might be exceeded for pitch >> 5 mm due to the zero-crossing

principle).

Figure 3 Speed Signal (half a period = 0.5 x 1/fspeed)

Figure 4 Definition of Rise and Fall Time, Duty = t1/T x 100%

AET03202

ransferred

peed Signal

ensor Internal

AET03203

10%

90%

50%

trtf

HIGH

ILOW t1

TLE4941

TLE4941C

Data Sheet 11 V2.1, 2005-02

Table 5 Electro Magnetic Compatibility (values depend on RM!)

Ref. ISO 7637-1; test circuit 1;

∆B = 2 mT (amplitude of sinus signal); VCC = 13.5 V, fB = 100 Hz; T = 25°C; RM ≥ 75 Ω

Parameter Symbol Level/Typ Status

Testpulse 1

Testpulse 2

Testpulse 3a

Testpulse 3b

Testpulse 4

Testpulse 5

VEMC IV / – 100 V

IV / 100 V

IV / – 150 V

IV / 100 V

IV / – 7 V

IV / 86.5 3) V

C 1)

B 2)

1) According to 7637-1 the supply switched “OFF” for t = 200 ms

2) According to 7637-1 for test pulse 4 the test voltage shall be 12 V ± 0.2 V. Measured with RM = 75 Ω only.

Mainly the current consumption will decrease. Status C with test circuit 1.

3) Applying in the board net a suppressor diode with sufficient energy absorption capability

Note: Values are valid for all TLE4941/42 types!

Ref. ISO 7637-3; test circuit 1;

∆B = 2 mT (amplitude of sinus signal); VCC = 13.5 V, fB = 100 Hz; T = 25°C; RM ≥ 75 Ω

Parameter Symbol Level/Typ Status

Testpulse 1

Testpulse 2

Testpulse 3a

Testpulse 3b

VEMC IV / – 30 V

IV / 30 V

IV / – 60 V

IV / 40 V

Note: Values are valid for all TLE4941/42 types!

Ref. ISO 11452-3; test circuit 1; measured in TEM-cell

∆B = 2 mT; VCC = 13.5 V, fB = 100 Hz; T = 25°C

Parameter Symbol Level/Typ Remarks

EMC field strength ETEM-Cell IV / 200 V/m AM = 80%, f = 1 kHz

Note: Only valid for non C- types!

Ref. ISO 11452-3; test circuit 1; measured in TEM-cell

∆B = 2 mT; VCC = 13.5 V, fB = 100 Hz; T = 25°C

Parameter Symbol Level/Typ Remarks

EMC field strength ETEM-Cell IV / 250 V/m AM = 80%,f = 1 kHz

Note: Only valid for C-types!

TLE4941

TLE4941C

Data Sheet 12 V2.1, 2005-02

Figure 5 Test Circuit 1

Figure 6 Distance Chip to Upper Side of IC

AES03199

GND

VCC Sensor

RMC2

VEMC

EMC-Generator Mainframe

Components: D1: 1N4007

D2: T 5Z27 1J

C1: 10 µF / 35 V

C2: 1 nF / 1000 V

RM:75 Ω / 5 W

PG-SSO-2-1/2 : 0.3

d : Distance chip to branded side of I

±0.08

AEA02961

Hall-Probe

Branded Side

TLE4941

TLE4941C

Data Sheet 13 V2.1, 2005-02

Package Outlines

Figure 7

0.1

6.35

±0.4

12.7

±0.3

CODE

45˚

12.7

±1

CODE CODE

-0.1

0.25

±0.05

7˚

0.2

+0.1

Adhesiv

±0.5

61-1

±0.5

Tape

0.39

±0.1

-0.15

0.25

±0.5

23.8

+0.75

-0.5

38 MAX.

3.38

3.71

(0.25)

±0.08

±0.06

1.9 MAX.

5.16

±0.08

5.34

±0.05

0.1 MAX.

1.9 MAX.

1.2±0.1

±0.05

0.87

±0.05

1.67

(14.8)

2.54

2 A

) No solder function area

Total tolerance at 10 pitches ±1

(Useable Length)

Tape

±1˚

0.2

0.5

1 MAX.1)

PG-SSO-2-1

(Plastic Single Small Outline Package)

GPO09296

TLE4941

TLE4941C

Data Sheet 14 V2.1, 2005-02

Figure 8

6.35±0.4

12.7±0.3

±0.3

CODE

45˚

12.7±1

CODE CODE

-0.1

0.25±0.05

7˚

0.2+0.1

Adhesiv

±0.5

61-1

±0.5

Tape

0.39±0.1

-0.15

0.25

±0.5

23.8

+0.75

-0.5

38 MAX.

0.65

3.38

3.71

(0.25)

±0.1

±0.08

±0.06

1.9 MAX.

5.16±0.08

5.34

±0.05

0.1 MAX.

1.9 MAX.

1.2±0.1

±0.05

0.87

±0.05

1.67

(14.8)

3.01

2.54

2 A

1) No solder function area

Total tolerance at 10 pitches ±1

(Useable Length)

±0.05

2.2

1.5±0.05

(2.4)

(2.7)

(1.3)

5.34±0.05

Tape

1.81±0.05

0.2 2x

0.5

1.2±0.05

5.16±0.08

A - A

Capacitor

(8.17)

±0.1

7.07

10.2±0.1

±0.05

0.25

0.2

±1˚

0.2

0.1

PG-SSO-2-2

(Plastic Single Small Outline Package)

GPO09448

ou can find all of our packages, sorts of packing and others in our

Infineon Internet Page “Products”: http://www.infineon.com/products. Dimensions in mm

TLE4941

TLE4941C

Data Sheet 15 V2.1, 2005-02

Appendix A

Typical Diagrams (measured performance)

Tc = Tcase, IC = approx. Tj - 5°C

Supply Current

Supply Current = f(Vcc)

Supply Current Ratio IHIGH / ILOW

Supply Current Ratio IHIGH/ILOW = f(Vcc)

-40

HIGH, ILOW

0 40 80 120 ˚C 20

AED03215

IHIGH

ILOW

IHIGH

ILOW

HIGH, ILOW

5 10 15 20 V 3

AED03217

-40

1.8

HIGH / ILOW

1.9

2.0

2.1

2.2

2.3

2.4

0 40 80 120 ˚C 20

AED03216

HIGH

ILOW

IHIGH

ILOW

1.6

5 10 15 20 V 3

AED03218

1.8

2.0

2.2

2.4

TLE4941

TLE4941C

Data Sheet 16 V2.1, 2005-02

Slew Rate without C, RM = 75 Ω

Slew Rate without C = f(RM)

Slew Rate with C = 1.8 nF, RM = 75 Ω

Slew Rate with C = 1.8 nF = f(RM)

-40

0 40 80 120 ˚C 20

AED03219

Slew Rate

mA/µs

Rise

Fall

AED03221

Slew Rate

A/µs

200 400 600 800 100

Ω

Rise

Fall

Rise

Fall

-40

0 40 80 120 ˚C 20

AED03220

Slew Rate

mA/µs

AED03222

Slew Rate

A/µs

200 400 600 800 100

Ω

Fall

Rise

TLE4941

TLE4941C

Data Sheet 17 V2.1, 2005-02

Magnetic Threshold

∆BLimit at f = 1 kHz

Jitter 1σ at ∆B = 2 mT, 1 kHz

Magnetic Threshold

∆BLimit = f(f)

Delaytime td

1) td is the time between the zero crossing of

∆B = 2 mT sinusoidal input signal and the rising

edge (50%) of the signal current.

-40

0.5

∆B

0 40 80 120 ˚C 20

AED03223

BLimit

0.6

0.7

0.8

0.9

1.0

-40

0 40 80 120 ˚C 20

AED03225

Jitter

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

100

0.5

BLimit

AED03224

0.6

0.7

0.8

0.9

1.0

BLimit

-40

˚C

AED03226

0 40 80 120 18

µs

d @ 2.5 kHz

TLE4941

TLE4941C

Data Sheet 18 V2.1, 2005-02

Appendix B

Release 1.0

Occurrence of Initial Calibration Delay Time td,input

If there is no input signal (standstill), a new initial calibration is triggered each 0.7 s. This

calibration has a duration td,input of max. 300 µs. No input signal change is detected during

that initial calibration time.

In normal operation (signal startup) the probability of td,input to come into effect is:

td,input / time frame for new calibration 300 µs/700 ms = 0.05%.

After IC resets (e.g. after a significant undervoltage) td,input will always come into effect.

Magnetic Input Signal Extremely Close to a Switching Threshold of PGA at Signal

Startup

After signal startup generally all PGA switching into the appropriate gain state happens

within less than one signal period. This is included in the calculation for nDZ-Start. For the

very rare case that the signal amplitude is extremely close to a PGA switching threshold

and the full range of following speed ADC respectively, a slight change of the signal

amplitude can cause one further PGA switching. It can be caused by non-perfect

magnetic signal (e.g. amplitude modulation due to tolerances of pole-wheel, tooth wheel

or air gap variation). This additional PGA switching can result in a further delay of the

output signal (nDZ-Start) up to three magnetic edges leading to a worst case of nDZ-Start = 9.

Due to the low probability of this case it is not defined as max. value in the data sheet.

(For a more detailed explanation please refer to the document “TLE4941/42 - Frequently

Asked Questions”).

TLE4941

TLE4941C

Data Sheet 19 V2.1, 2005-02

For questions on technology, delivery and prices please contact the Infineon

Technologies offices in Germany or the Infineon Technologies Companies and

Representatives worldwide: see our webpage at http://www.infineon.com

Revision History:2005-02, V2.1

Previous Version: 2004-01, V2.0

Page Subjects (major changes since last revision)

3,13,14 Package name changed from P-... to PG-...

13,14 Figure 7,8: Package Outline PG-SSO-2-1, PG-SSO-2-2

- Tape thickness changed from 0.50±0.1mm to 0.39±0.1 mm

- Package mold dimension changed from 5.38±0.05 mm to 5.34±0.05 mm

(Note: only the dimensions in the drawing changed, but not the package

dimensions)

15-17 Appendix A inserted

18 Appendix B inserted

-New format of data sheet

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Published by Infineon Technologies AG