Datasheet TDA5142T-C2 Datasheet (Philips)

DATA SH EET

Product specification
Supersedes data of March 1992
File under Integrated Circuits, IC11

June 1994

INTEGRATED CIRCUITS

Philips Semiconductors

TDA5142T

Brushless DC motor drive circuit

June 1994 2

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

FEATURES

• Full-wave commutation without position sensors

• Built-in start-up circuitry

• Six outputs that can drive three external transistor pairs:

– output current 0.2 A (typ.)
– low saturation voltage
– built-in current limiter

• Thermal protection

• Tacho output without extra sensor

• Transconductance amplifier for an external

control transistor

• Motor brake facility.

APPLICATIONS

• High-power applications e.g.:
– high-end hard disk drives
– automotive.

GENERAL DESCRIPTION

The TDA5142T is a bipolar integrated circuit used to drive
3-phase brushless DC motors in full-wave mode. The
device is sensorless (saving of 3 hall-sensors) using the
back-EMF sensing technique to sense the rotor position.
It includes a brake function and 6 pre-drivers able to
control FETs or bipolar external transistors. It is ideally
suited for high-power applications such as high-end hard
disk drives, automotive and other applications.

QUICK REFERENCE DATA

Measured over full voltage and temperature range.

Note

1. An unstabilized supply can be used.

ORDERING INFORMATION

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

V

P

supply voltage note 1 4 − 18 V

V

VMOT

input voltage to the output
driver stages

3 − 18 V

V

O

driver output voltage IO= 100 mA; lower transistor −−0.35 V

I

O

= 100 mA; upper transistor 1.05 −−V

I

LIM

current limiting V

VMOT

= 14.5 V; RO=47Ω 150 200 250 mA

TYPE NUMBER

PACKAGE

PINS PIN POSITION MATERIAL CODE

TDA5142T 24 SOL plastic SOT137-1

June 1994 3

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

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Fig.1 Block diagram.

June 1994 4

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

PINNING

SYMBOL PIN DESCRIPTION

OUT-NB 1 driver output B for driving the n-channel power FET or power NPN
OUT-PB 2 driver output B for driving the n-channel power FET or power PNP
GND1 3 ground (0 V) motor supply return for output stages
OUT-PC 4 driver output C for driving the n-channel power FET or power PNP
OUT-NC 5 driver output C for driving the n-channel power FET or power NPN
VMOT 6 input voltage for the output driver stages
TEST 7 test input/output
BRAKE 8 brake input
FG 9 frequency generator: output of the rotation speed detector stage
GND2 10 ground supply return for control circuits
V

P

11 supply voltage
CAP-CD 12 external capacitor connection for adaptive communication delay timing
CAP-DC 13 external capacitor connection for adaptive communication delay timing copy
CAP-ST 14 external capacitor connection for start-up oscillator
CAP-TI 15 external capacitor connection for timing
+AMP IN 16 non-inverting input of the transconductance amplifier

−AMP IN 17 inverting input of the transconductance amplifier
AMP OUT 18 transconductance amplifier output (open collector)
COMP-A 19 comparator input corresponding to output A
COMP-B 20 comparator input corresponding to output B
COMP-C 21 comparator input corresponding to output C
MOT0 22 input from the star point of the motor coils
OUT-NA 23 driver output A for driving the n-channel power FET or power NPN
OUT-PA 24 driver output A for driving the n-channel power FET or power PNP

June 1994 5

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

Fig.2 Pin configuration.

FUNCTIONAL DESCRIPTION

The TDA5142T offers a sensorless three phase motor
drive function. It is unique in its combination of sensorless
motor drive and full-wave drive. The TDA5142T offers
protected outputs capable of driving external power FETs
or bipolar power transistors. It can easily be adapted for
different motors and applications. The TDA5142T offers
the following features:

• Sensorless commutation by using the motor EMF.

• Built-in start-up circuit.

• Optimum commutation, independent of motor type or

motor loading.

• Six output drivers.

• Maximum output current 0.25 A.

• Outputs protected by current limiting and thermal

protection.

• Low current consumption.

• Accurate frequency generator (FG) by using the

motor EMF.

• Brake function.

• Uncommitted operational transconductance amplifier

(OTA), with a high output current, for use as a control
amplifier or as a level shifter in a Switched Mode Power
Supply (SMPS) drive.

LIMITING VALUES

In accordance with the Absolute Maximum Rating System (IEC 134).

SYMBOL PARAMETER CONDITIONS MIN. MAX. UNIT

V

P

supply voltage 4 18 V

V

I

input voltage; all pins except
VMOT

VI< 18 V −0.3 VP + 0.5 V

V

VMOT

VMOT input voltage 3 18 V

V

O

output voltage

FG GND V

P

V
AMP OUT − 18 V
OUT-NA, OUT-NB and OUT-NC − V

VMOT

− 0.9 V

OUT-PA, OUT-PB and OUT-PC 0.2 − V

V

I

input voltage CAP-ST, CAP-TI,
CAP-CD and CAP-DC

− 2.5 V

T

stg

storage temperature −55 +150 °C

T

amb

operating ambient temperature 0 +70 °C

P

tot

total power dissipation see Fig.3 −− W

V

es

electrostatic handling see Chapter “Handling” − 500 V

June 1994 6

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

P

tot

(W)

50

3

2

0

0 200

MLB777

50 100 150

T ( C)

amb

o

70

1

Fig.3 Power derating curve.

HANDLING

Every pin withstands the ESD test according to

“MIL-STD-883C class 2”

. Method 3015 (HBM 1500 Ω,
100 pF) 3 pulses + and 3 pulses − on each pin referenced
to ground.

CHARACTERISTICS

V

P

= 14.5 V; T

amb

=25°C; unless otherwise specified.

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

Supply

V

P

supply voltage note 1 4 − 18 V

I

P

supply current note 2 − 5.2 6.25 mA

V

VMOT

input voltage to the output driver
stages

see Fig.1 3 − 18 V

Thermal protection

T

SD

local temperature at temperature
sensor causing shut-down

130 140 150 °C

∆T reduction in temperature before

switch-on

after shut-down − T

SD

− 30 − K

COMP-A, COMP-B, COMP-C and MOT0

V

I

input voltage −0.5 − V

VMOT

V

I

I

input bias current 0.5 V < VI< V

VMOT

− 1.5 V −10 − 0 µA

V

CSW

comparator switching level note 3 ±20 ±25 ±30 mV

∆V

CSW

variation in comparator switching
levels

−3 0 +3 mV

V

hys

comparator input hysteresis − 75 −µV

June 1994 7

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

OUT-NA, OUT-NB, OUT-NC, OUT-PA, OUT-PB and OUT-PC

V

O-n

n-channel driver output voltage upper transistor;

IO= −100 mA

−1.05 −−V

lower transistor;
I

O

=10mA

−− 0.35 V

V

O-p

p-channel driver output voltage upper transistor;

IO= −10 mA

−1.05 −−V

lower transistor;
I

O

= 100 mA

−− 0.35 V

∆V

OL

variation in saturation voltage
between lower transistors

IO= 100 mA −− 180 mV

∆V

OH

variation in saturation voltage
between upper transistors

IO= −100 mA −− 180 mV

I

LIM

current limiting V

VMOT

= 14.5 V;

RO=47Ω

150 200 250 mA

+AMP IN and −AMP IN

V

I

input voltage −0.3 − VP− 1.7 V
differential mode voltage without

‘latch-up’

−− ±V

P

V

I

b

input bias current −− 650 nA

C

I

input capacitance − 4 − pF

V

offset

input offset voltage −− 10 mV

AMP OUT (open collector)

I

sink

output sink current 40 −−mA

V

sat

saturation voltage II=40mA − 1.5 2.1 V

V

O

output voltage −0.5 − +18 V

SR slew rate R

L

= 330 Ω; CL=50pF 40 −−mA/µs

G

tr

transfer gain 0.3 −−S

BRAKE

V

BM

brake-mode voltage enable brake mode;

4V<VP<18V

− 2.3 V

normal mode;
4V<V

P

<18V

2.7 − V

I

I

input current brake mode −−20 −30 µA

normal mode − 020µA

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

June 1994 8

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

Notes

1. An unstabilized supply can be used.

2. V

VMOT=VP

, all other inputs at 0 V; all outputs at VP; IO= 0 mA.

3. Switching levels with respect to driver outputs OUT-NA, OUT-NB, OUT-NC, OUT-PA, OUT-PB and OUT-PC.

FG (push-pull)

V

OL

LOW level output voltage IO= 1.6 mA −− 0.4 V

V

OH

HIGH level output voltage IO= −60 µAV

P

−0.3 − V

t

THL

HIGH-to-LOW transition time CL= 50 pF; RL=10kΩ− 0.5 −µs
ratio of FG frequency and

commutation frequency

− 1 −

CAP-ST

I

sink

output sink current 1.5 2.0 2.5 µA

I

source

output source current −2.5 −2.0 −1.5 µA

V

SWL

LOW level switching voltage − 0.20 − V

V

SWH

HIGH level switching voltage − 2.20 − V

CAP-TI

I

sink

output sink current − 28 −µA

I

source

output source current 0.2 V < V

CAP-TI

< 0.3 V −−57 −µA

0.3V<V

CAP-TI

< 2.2 V −−5−µA

V

SWL

LOW level switching voltage − 50 − mV

V

SWM

MIDDLE level switching voltage − 0.30 − V

V

SWH

HIGH level switching voltage − 2.20 − V

CAP-CD

I

sink

output sink current 10.6 16.2 22 µA

I

source

output source current −5.3 −8.1 −11 µA

I

sink/Isource

ratio of sink to source current 1.85 2.05 2.25

V

IL

LOW level input voltage 850 875 900 mV

V

IH

HIGH level input voltage 2.3 − 2.5 V

CAP-DC

I

sink

output sink current 10.1 15.5 20.9 µA

I

source

output source current −20.9 −15.5 −10.1 µA

I

sink/Isource

ratio of sink to source current 0.9 1.025 1.15

V

IL

LOW level input voltage 850 875 900 mV

V

IH

HIGH level input voltage 2.3 − 2.5 V

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

June 1994 9

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

APPLICATION INFORMATION

(1) RX = RY > 8 (VMOT − 1.5)

Fig.4 Application diagram without use of the operational transconductance amplifier (OTA) with bipolar

power transistors.

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June 1994 10

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

Fig.5 Application diagram without use of the operational transconductance amplifier (OTA)

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June 1994 11

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

Introduction (see Fig.6)

Full-wave driving of a three phase motor requires three
push-pull output stages. In each of the six possible states
two outputs are active, one sourcing (H) and one sinking
(L). The third output presents a high impedance (Z) to the
motor, which enables measurement of the motor
back-EMF in the corresponding motor coil by the EMF
comparator at each output. The commutation logic is
responsible for control of the output transistors and
selection of the correct EMF comparator. In Table 1 the
sequence of the six possible states of the external
connected output transistors has been depicted and the
corresponding output levels on the NA, PA, NB, PB, NC
and PC outputs of the TDA5142T.

Table 1 Output states.

Note

1. H = HIGH state; L = LOW state; Z = high-impedance OFF-state.

STATE MOT1

(1)

OUT­NA

(1)

OUT-

PA

(1)

MOT2

(1)

OUT­NB

(1)

OUT­PB

(1)

MOT3

(1)

OUT­NC

(1)

OUT­PC

(1)

1ZLHLHHHLL
2HLLLHHZLH
3HLLZLHLHH
4Z L H H L L L H H
5LHHHLLZLH
6L HH Z L H H L L

The zero-crossing in the motor EMF (detected by the
comparator selected by the commutation logic) is used to
calculate the correct moment for the next commutation,
that is, the change to the next output state. The delay is
calculated (depending on the motor loading) by the
adaptive commutation delay block.

The output stages are also protected by a current limiting
circuit and by thermal protection.

The detected zero-crossings are used to provide speed
information. The information has been made available on
the FG output pin. This output provides an output signal
with a frequency equal to the commutation frequency.

The system will only function when the EMF voltage from
the motor is present. Therefore, a start oscillator is
provided that will generate commutation pulses when no
zero-crossings in the motor voltage are available.

A timing function is incorporated into the device for internal
timing and for timing of the reverse rotation detection.

The TDA5142T also contains an uncommitted
transconductance amplifier (OTA) that can be used as a
control amplifier. The output is capable of directly driving
an external power transistor.

The TDA5142T is designed for systems with low current
consumption: use of I

2

L logic, adaptive base drive for the

output transistors (patented).

Adjustments

The system has been designed in such a way that the
tolerances of the application components are not critical.
However, the approximate values of the following
components must still be determined:

• The start capacitor; this determines the frequency of the

start oscillator.

• The two capacitors in the adaptive commutation delay

circuit; these are important in determining the optimum
moment for commutation, depending on the type and
loading of the motor.

• The timing capacitor; this provides the system with its

timing signals.

T

HE START CAPACITOR (CAP-ST)

This capacitor determines the frequency of the start
oscillator. It is charged and discharged, with a current of
2 µA, from 0.05 to 2.2 V and back to 0.05 V. The time
taken to complete one cycle is given by:
t

start

= (2.15 × C) s (with C in µF)

The start oscillator is reset by a commutation pulse and so
is only active when the system is in the start-up mode. A
pulse from the start oscillator will cause the outputs to
change to the next state (torque in the motor).

June 1994 12

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

If the movement of the motor generates enough EMF the
TDA5142T will run the motor. If the amount of EMF
generated is insufficient, then the motor will move one step
only and will oscillate in its new position. The amplitude of
the oscillation must decrease sufficiently before the arrival
of the next start pulse, to prevent the pulse arriving during
the wrong phase of the oscillation. The oscillation of the
motor is given by:

where:

K

t

= torque constant (N.m/A)
I = current (A)
p = number of magnetic pole-pairs
J = inertia J (kg.m2).

Example: J = 72 × 10−6kg.m2, K = 25 × 10−3N.m/A, p = 6
and I = 0.5 A; this gives f

osc

= 5 Hz. If the damping is high
then a start frequency of 2 Hz can be chosen or
t = 500 ms, thus C = 0.5/2 = 0.25 µF (choose 220 nF).

T

HE ADAPTIVE COMMUTATION DELAY (CAP-CD AND

CAP-DC)
In this circuit capacitor CAP-CD is charged during one

commutation period, with an interruption of the charging
current during the diode pulse. During the next
commutation period this capacitor (CAP-CD) is discharged
at twice the charging current. The charging current is

8.1 µA and the discharging current 16.2 µA; the voltage
range is from 0.9 to 2.2 V. The voltage must stay within
this range at the lowest commutation frequency of
interest, f

C1

:

(C in nF)

If the frequency is lower, then a constant commutation
delay after the zero-crossing is generated by the discharge
from 2.2 to 0.9 V at 20 µA;
maximum delay = (0.076 × C) ms (with C in nF)

Example: nominal commutation frequency = 900 Hz and
the lowest usable frequency = 400 Hz; so:

(choose 18 nF)

The other capacitor, CAP-DC, is used to repeat the same
delay by charging and discharging with 15.5 µA. The same
value can be chosen as for CAP-CD. Figure 7 illustrates
typical voltage waveforms.

f

osc

1

2π

K

t

I× p×

J

---------------------- -

---------------------------------- -

=

C

8.1 10

6–

×

f1.3×

--------------------------

6231

f

C1

------------ -

==

CAP-CD

6231

400

------------ -

15.6==

June 1994 13

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

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BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB

B

BBBBBB

BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB

B

BBBBBB

BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB

B

BBBBBB

BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB

B

BBBBBB

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

B

BBBBB

B

BBBBBBB

B

BBBBBB

B

B

BBBBBB

B

B

BBBBBB

B

B

BBBBBB

B

B

BBBBBB

B

B

BBBBBB

B

B

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B

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B

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B

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B

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B

BBBBBBBB

Fig.6 Typical application of the TDA5142T as a scanner driver, with use of OTA.

June 1994 14

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

Fig.7 CAP-CD and CAP-DC typical voltage waveforms in normal running mode.

THE TIMING CAPACITOR (CAP-TI)
Capacitor CAP-TI is used for timing the successive steps

within one commutation period; these steps include some
internal delays.

The most important function is the watchdog time in which
the motor EMF has to recover from a negative diode-pulse
back to a positive EMF voltage (or vice versa). A watchdog
timer is a guarding function that only becomes active when
the expected event does not occur within a predetermined
time.

The EMF usually recovers within a short time if the motor
is running normally (<<ms). However, if the motor is
motionless or rotating in the reverse direction, then the
time can be longer (>>ms).

A watchdog time must be chosen so that it is long enough
for a motor without EMF (still) and eddy currents that may
stretch the voltage in a motor winding; however, it must be
short enough to detect reverse rotation. If the watchdog

time is made too long, then the motor may run in the wrong
direction (with little torque).

The capacitor is charged, with a current of 57 µA, from

0.2 to 0.3 V. Above this level it is charged, with a current of
5 µA, up to 2.2 V only if the selected motor EMF remains
in the wrong polarity (watchdog function). At the end, or, if
the motor voltage becomes positive, the capacitor is
discharged with a current of 28 µA. The watchdog time is
the time taken to charge the capacitor, with a current of
5 µA, from 0.3 to 2.2 V.

To ensure that the internal delays are covered CAP-TI
must have a minimum value of 2 nF. For the watchdog
function a value for CAP-TI of 10 nF is recommended.

To ensure a good start-up and commutation, care must be
taken that no oscillations occur at the trailing edge of the
flyback pulse. Snubber networks at the outputs should be
critically damped.

Typical voltage waveforms are illustrated by Fig.8.

June 1994 15

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

Fig.8 Typical CAP-TI and V

MOT1

voltage waveforms in normal running mode.

If the chosen value of CAP-TI is too small oscillations can occur in certain positions of a blocked rotor. If the chosen value is too large, then it
is possible that the motor may run in the reverse direction (synchronously with little torque).

Other design aspects

There are other design aspects concerning the application
of the TDA5142T besides the commutation function. They
are:

• Generation of the tacho signal FG

• General purpose operational transconductance

amplifier (OTA)

• Possibilities of motor control

• Brake function

• Reliability.

FG

SIGNAL

The FG signal is generated in the TDA5142T by using the
zero-crossing of the motor EMF from the three motor
windings and the commutation signal.

Output FG switches from HIGH-to-LOW on all zero
crossings and from LOW-to-HIGH on all commutations.
Output FG can source typically 75 µA and sink more
than 3 mA.

Example: a 3-phase motor with 6 magnetic pole-pairs at
1500 rpm and with a full-wave drive has a commutation
frequency of 25 × 6 × 6 = 900 Hz, and generates a tacho
signal of 900 Hz.

T

HE OPERATIONAL TRANSCONDUCTANCE AMPLIFIER (OTA)

The OTA is an uncommitted amplifier with a high output
current (40 mA) that can be used as a control amplifier.
The common mode input range includes ground (GND)
and rises to VP− 1.7 V. The high sink current enables the
OTA to drive a power transistor directly in an analog
control amplifier.

Although the gain is not extremely high (0.3 S), care must
be taken with the stability of the circuit if the OTA is used
as a linear amplifier as no frequency compensation has
been provided.

The convention for the inputs (inverting or not) is the same
as for a normal operational amplifier: with a resistor (as
load) connected from the output (AMP OUT) to the positive
supply, a positive-going voltage is found when the
non-inverting input (+AMP IN) is positive with respect to
the inverting input (−AMP IN). Confusion is possible
because a ‘plus’ input causes less current, and so a
positive voltage.

M

OTOR CONTROL

DC motors can be controlled in an analog manner using
the OTA.

For the analog control an external transistor is required.
The OTA can supply the base current for this transistor
and act as a control amplifier (see Fig.6).

June 1994 16

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

BRAKE FUNCTION

• If the voltage on pin 8 is <2.3 V the motor brakes; in this

condition the external outputs are driven to a HIGH
voltage level.

• If pin 8 is floating or the voltage is >2.7 V the motor

runs normally.

R

ELIABILITY

It is necessary to protect high current circuits and the
output stages are protected in two ways:

• Current limiting of the ‘lower’ output transistors. The

‘upper’ output transistors use the same base current as
the conducting ‘lower’ transistor (+15%). This means
that the current to and from the output stages is limited.

• Thermal protection of the six output transistors is

achieved in such a way that the transistors are switched
off when the local temperature becomes too high.

June 1994 17

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

PACKAGE OUTLINE

Fig.9 Plastic small outline package; 24 leads; large body (SOT137-1; SO24L).

Dimensions in mm.

handbook, full pagewidth

7.6

7.4

10.65

10.00

A

MBC235 - 1

0.3

0.1

2.45

2.25

1.1

0.5

0.32

0.23

1.1

1.0

0 to 8

o

2.65

2.35

detail A

S

15.6

15.2

0.1 S

112

1324

pin 1

index

0.9

0.4

(4x)

0.25 M

(24x)

0.49

0.36

1.27

June 1994 18

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

SOLDERING
Plastic small-outline packages

B

YWAVE

During placement and before soldering, the component
must be fixed with a droplet of adhesive. After curing the
adhesive, the component can be soldered. The adhesive
can be applied by screen printing, pin transfer or syringe
dispensing.

Maximum permissible solder temperature is 260 °C, and
maximum duration of package immersion in solder bath is
10 s, if allowed to cool to less than 150 °C within 6 s.
Typical dwell time is 4 s at 250 °C.

A modified wave soldering technique is recommended
using two solder waves (dual-wave), in which a turbulent
wave with high upward pressure is followed by a smooth
laminar wave. Using a mildly-activated flux eliminates the
need for removal of corrosive residues in most
applications.

B

Y SOLDER PASTE REFLOW

Reflow soldering requires the solder paste (a suspension
of fine solder particles, flux and binding agent) to be

applied to the substrate by screen printing, stencilling or
pressure-syringe dispensing before device placement.

Several techniques exist for reflowing; for example,
thermal conduction by heated belt, infrared, and
vapour-phase reflow. Dwell times vary between 50 and
300 s according to method. Typical reflow temperatures
range from 215 to 250 °C.

Preheating is necessary to dry the paste and evaporate
the binding agent. Preheating duration: 45 min at 45 °C.

R

EPAIRING SOLDERED JOINTS (BY HAND-HELD SOLDERING

IRON OR PULSE

-HEATED SOLDER TOOL)

Fix the component by first soldering two, diagonally
opposite, end pins. Apply the heating tool to the flat part of
the pin only. Contact time must be limited to 10 s at up to
300 °C. When using proper tools, all other pins can be
soldered in one operation within 2 to 5 s at between 270
and 320 °C. (Pulse-heated soldering is not recommended
for SO packages.)

For pulse-heated solder tool (resistance) soldering of VSO
packages, solder is applied to the substrate by dipping or
by an extra thick tin/lead plating before package
placement.

DEFINITIONS

LIFE SUPPORT APPLICATIONS

These products are not designed for use in life support appliances, devices, or systems where malfunction of these
products can reasonably be expected to result in personal injury. Philips customers using or selling these products for
use in such applications do so at their own risk and agree to fully indemnify Philips for any damages resulting from such
improper use or sale.

Data sheet status

Objective specification This data sheet contains target or goal specifications for product development.
Preliminary specification This data sheet contains preliminary data; supplementary data may be published later.
Product specification This data sheet contains final product specifications.

Limiting values

Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or
more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation
of the device at these or at any other conditions above those given in the Characteristics sections of the specification
is not implied. Exposure to limiting values for extended periods may affect device reliability.

Application information

Where application information is given, it is advisory and does not form part of the specification.

June 1994 19

Philips Semiconductors Product specification

Brushless DC motor drive circuit TDA5142T

NOTES

Philips Semiconductors

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SCD31 © Philips Electronics N.V. 1994

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373061/1500/02/pp20 Date of release: June 1994
Document order number: 9397 735 80011