PHILIPS TDA5240

Product specification
File under Integrated
Philips
Semiconductors
November
Circuits,
ICO1
re
96
Philips Semiconductors
Brushless
Product specification
DC motor
drive
TDA5240T
circuit
FEATURES
.Full-wave
commutation
.Built-in
(using push/pull
.Optimum
commutation
.Built-in
independent
on motor type or motor loading
flyback diodes
.Three
push-pull
-0.85
outputs:
A output current
-built-in
current limiter
.Thermal
protection
.Soft
slope outputs for low radiation.
.Low
current consumption
.Tacho
drivers at the output stages) without position sensors
start-up circuit
by adaptative
base-drive
output without extra sensor.
.Comparator
.Built-in
for external
multiplexer
position generator
combining
(PG) signal
internal FG and external
PG signal on one pin for easy use with a controlling
microprocessor
.Linear
.PG
control of the output stages
signal output.
APPLICATIONS
.General
GENERAL
purpose
spindle
driver
( e.g. VCR
scanner
motor).
DESCRIPTION
The TDA5240T is a bipolar integrated circuit used to drive brushless DC motors in full-wave mode. The device senses
the rotor position using an EMF-sensing technique and is ideally suited as a drive circuit for VCR scanner motors.
QUICK REFERENCE DATA
Measured over full voltage and temperature
SYMBOL
ranges
PARAMETER
MIN.
Vp
supply voltage range (note 1)
4
IUM
current limiting
0.6
Vo
output
voltage
at 10 = 100 mA(Upper
+ Lower
transistor)
18
0.85
1
0.93
1.05
Note
1.
An unstabilized
supply can be used;
Transients
of 2 V allowed with max slope 0.1 V/J.ls.
8
November
96
2/19
UNIT
MAX.
TYPo
~
Philips
Product specification
Semiconductors
Brushless
DC motor drive circuit
TDA5240T
ORDERING INFORMATION
PACKAGE
TYPE NUMBER
NAME
TDA5240T
SO20L
DESCRIPTION
20-pin small-outline; plastic
Fig.1
November
96
Power derating curve
3119
VERSION
SOT163AH17
Philips
Product specification
Semiconductors
Brushless
DC motor drive circuit
TDA5240T
BLOCK DIAGRAM
r
VP
CAP-CPC
,
CTLIf'I
.
CAPST
MOT1
CAPCDSI
CAPCDM
..
MOT2
CAPTII
-
I
I
PGOUTI
.
,,1
~I
MOT3
PGFG
'\'
r'
-
IMOTO
-
L
T
PGlfr
Fig.2
.GND2-
Block
diagram.
.
November 96
4/19
-tND1-
J
Philips Semiconductors
Product specification
Brushless DC motor drive circuit
TDA5240T
PINNING
SYMBOL
PIN
DESCRIPTION
GND1
1
ground (0 V) motor supply return for output stages
n.c.
2
not connected
MOT2
3
driver output 2
n.c.
4
not connected
VP
5
positive supply voltage
PGIN
6
position generator: input from the position detector sensor to the position detector
stage (optional)
FGPG
7
FG/PG (open collector)
GND2
8
ground supply return for control circuits
PGOUT
9
position generator output of the position detector stage
CAP–CDM
10
external capacitor connection for commutation delay timing
CAP–CDS
11
external capacitor connection for commutation delay timing copy
CAP–ST
12
external capacitor connection for start–up oscillator
CAP–TI
13
external capacitor connection for timing
CTL IN
14
non–inverting input of the control amplifier
MOT0
15
input from the start point of the motor coils
CAP–CPC
16
external capacitor for stability of control loop
n.c.
17
not connected
MOT3
18
driver output 3
n.c.
19
not connected
MOT1
20
driver output 1
GND1
1
20
MOT1
n.c.
2
19
n.c.
MOT2
3
18
MOT3
NC
4
17
n.c.
VP
5
16
CAP–CPC
PGIN
6
15
MOT0
FGPG
7
14
CTL IN
GND2
8
13
CAP–TI
PGOUT
9
12
10
11
CAP–CDM
TDA5240T
Fig. 3 Pin configuration
November 96
5/19
CAP–ST
CAP–CDS
Philips
Product specification
Semiconductors
Brushless
FUNCTIONAL
DC motor drive circuit
TDA5240T
DESCRIPTION
The TDA5240T offers a sensorless
drive and full-wave drive.
three phase motor drive function.
It is unique in its combination
of sensorless
motor
The TDA5240T offers protected outputs capable of handling high currents and can be used with star or delta connected
motors. It can easily be adapted for different motors and applications.
The TDA5240T
offers the following
.Sensorless
.Built-in
commutation
features:
by using the motor EMF
start-up circuit
.Optimum
commutation,
.Built-in
flyback diodes
.Three
phase full-wave
.High
independent
of motor type or motor loading
drive
output current (0.85 A)
.Outputs
protected
by current limiting and thermal protection
.Low
current consumption
.Soft
slope outputs for low radiation
.Accurate
frequency
.Comparator
.Built-in
generator
for external
multiplexer
by adaptive
base-drive
(FG) by using the motor EMF
position generator
combining
of each output transistor
(PG) signal
internal FG and external
PG signals on one pin for easy use with a controlling
microprocessor
.Linear
LIMITING
control of the output stages.
VALUES
In accordance
with the Absolute
Maximum
PARAMETER
SYMBOL
.
Rating System (IEC 134).
MIN.
18
Vp
supply voltage
VI
input
Vo
output voltage;
Vo
output voltage;
VI
input voltage; CAP-ST, CAP- TI, CAP-CD and CAP-DC
I Ptot
I total
voltage;
power
-0.3
Vp + 0.5
PGOUT and PG/FG
GND
Vp
MOTO, MOT1, MOT2 and MOT3
-1
Vp + VD
all pins
except
Vp (VI < 8 V)
UNIT
MAX.
2.5
v
v
v
v
v
see power
dissipation
derating
curve
~
I Tamb
I~ge
operating
temperature
range
ambient temperature
range
-
November 96
6/19
-55
+150
-10
+70
°c
°c
Philips Semiconductors
Product specification
Brushless DC motor drive circuit
TDA5240T
CHARACTERISTICS
VP = 14.5 V "10%; Tamb = –10 °C to 70 °C, unless otherwise specified
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
VP
Supply voltage range
note 1
4
–
18
V
IP
Input current range
note 2
–
5.3
7
mA
130
140
150
°C
–
TSD–30
–
°C
Supply
Thermal protection
TSD
Local temperature at temperature
sensor causing shut–down
DT
Reduction in temperature
before switch–on
after shut–down
MOT0 – CENTER TAP
VI
Input voltage range
–0.5
–
VP
V
II
Input bias current
0.5 V<VI <VP–1.5 V
–10
–
–
mA
VCSW
Comparator Switching Level
note 3
20
30
40
mV
DVCS
Variations in comparator switching
levels
–3
0
+3
mV
VH
Comparator input hysteresis
–
75
–
mV
MOT1, MOT2 AND MOT3
Voltage drop at 25 °C
IO = 100 mA
–
0.93
1.05
V
(Vout upper stage + Vout lower stage)
IO = 500 mA
–
1.65
1.9
V
DVOL
Variation in voltage between lower
transistors
in control mode;
IO = 100 mA
–
–
150
mV
DVOH
Variation in voltage between upper
transistors
in control mode;
IO = –100 mA
–
–
150
mV
ILIM
Current limiting
12 V/6.8W
0.6
0.85
1
A
Tr
Rise time switching output between
1.9 and 12.2 V
IO = 250 mA
7
12
17
ms
Tf
Fall time switching output between
12.2 and 1.9 V
IO = 250 mA
16
23
30
ms
VDHF
Diode forward voltage (DH)
notes 4 and 5; see Fig. 2;
IO = –500 mA
–
–
1.5
V
VDLF
Diode forward voltage (DL)
notes 4 and 5; see Fig. 2;
IO = 500 mA
–1.5
–
–
V
IDM
Peak diode current
note 5
–
–
1
A
0
–
VP
V
VDO
CTL IN
VCTLIN
Input voltage range
VCTLIN0
Offset voltage
See Fig. 6
VCAPCPC v 1.1 V
0.7
–
–
V
GTRAN
Transfer gain
CAP–CPC = 100 nF
VCTLIN = 1.5V and
VCTLIN = 3 V
4.5
5
5.5
V/V
November 96
7/19
Philips Semiconductors
Product specification
Brushless DC motor drive circuit
Symbol
Parameter
TDA5240T
Conditions
Min
Typ
Max
Unit
PG IN
VI
Input voltage range
–0.3
–
+5
V
IB
Input bias current
–
–
650
nA
RI
Input resistance
5
–
30
kW
VCSW
Comparator switching level
86
93
107
mV
+/–VIAMP
Comparator input hysteresis
–
8
–
mV
–
–
0.4
V
–
–
VP
V
–
0.5
–
ms
4
–
10
ms
–
–
0.4
V
–
–
VP
V
–
0.5
–
ms
Ratio of FG frequency and
commutation frequency
–
1:2
–
–
d
Duty factor
–
50
–
%
tPL
Pulse width LOW
5
7
15
ms
PG OUT (open collector)
VOL
Output voltage LOW
VOHmax
Output voltage HIGH
tTHL
Transition time
tPL
Pulse width LOW
IO = 1.6 mA
HIGH-to-LOW;
CL = 50 pF;
RL = 10 kW
FG/PG (open collector)
VOL
Output voltage LOW
VOHmax
Maximum output voltage HIGH
tTHL
Transition time
IO =1.6 mA
HIGH–to–LOW
CL = 50 pF
RL = 10 kW
after a PG IN pulse
CAP–ST
II
Output sink current
1.5
2.0
2.5
mA
IO
Output source current
–2.5
–2.0
–1.5
mA
VSWL
Lower switching level
–
0.20
–
V
VSWM
Middle switching level
–
0.30
–
V
VSWH
Upper switching level
–
2.20
–
V
II
Output sink current
22
30
38
mA
IOH
Output source current HIGH
–70
–63
–56
mA
IOL
Lower source current LOW
–6.0
–5.3
–4.6
mA
VSWL
Lower switching level
–
50
–
mV
VSWM
Middle switching level
–
0.30
–
V
VSWH
Upper switching level
–
2.20
–
V
II
Output sink current
10.6
16.2
22
mA
IO
Output source current
–5.3
–8.1
–11
mA
II/IO
Ratio of sink to source current
1.85
2.05
2.25
VIL
Input voltage level LOW
780
860
940
mV
VIH
Input voltage level HIGH
2.3
2.4
2.55
V
CAP–TI
CAP–CDM
November 96
8/19
Philips Semiconductors
Product specification
Brushless DC motor drive circuit
Symbol
Parameter
TDA5240T
Conditions
Min
Typ
Max
Unit
CAP–CDS
II
Output sink current
10.1
15.5
20.9
A
IO
Output source current
–20.9
–15.5
–10.1
A
II/IO
Ratio of sink to source current
0.9
1.025
1.15
VIL
Input voltage level LOW
780
860
940
mV
VIH
Input voltage level HIGH
2.3
2.4
2.55
V
II
Output sink current
1
–
3
mA
IO
Output source current
–100
–
–30
CAP–CPC
NOTES:
1. An unstabilized supply can be used; transients of 2 V allowed with max slope 0.1 V/ s.
2. All other inputs at 0 V; all outputs at VP and IO = 0 A.
3. Switching levels with respect to MOT1, MOT2 and MOT3.
4. Drivers are in high impedance OFF–state.
5. The outputs are short–circuit protected by limiting the current and the IC temperature.
Fig. 4 Switching levels
November 96
9/19
A
Philips Semiconductors
Product specification
Brushless DC motor drive circuit
TDA5240T
APPLICATION INFORMATION
Introduction
Figure 5 shows 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 and one sinking current. The third output presents a high impedance to the motor which enables measurement of the
motor 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.
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.
Because of high inductive loading the output stages contain flyback diodes. The output stages are also protected by a current limiting circuit and
by thermal protection of the six output transistors.
The zero–crossings can be used to provide speed information such as the tacho signal FG. A VCR scanner also requires a PG phase sensor.
This circuit has an interface for a simple pick–up coil. A multiplexer circuit is also provided to combine the FG and PG signals in time. The
TDA5240 is providing 1 multiplexed FG PG signal: pin7 (SO20) FG–PG 3 times the number of pole pairs. A PG output signal is generated;
pulse width is typically 7 µs.
Table 1 OUTPUT STATES
STATE
1
2
3
4
5
6
MOT1
Z
H
H
Z
L
L
MOT2
L
L
Z
H
H
Z
MOT3
H
Z
L
L
Z
H
In Table 1, the sequence of the six possible states of the outputs has been depicted
November 96
10/19
Philips Semiconductors
Brushless
Product specification
DC motor drive circuit
TDA5240T
Fig.5 Typical application
November
96
11/19
of the TDA5240T.
Philips
Product specification
Semiconductors
Brushless
DC motor drive circuit
TDA5240T
Analog control of the motor output voltages is achieved by an internal operational amplifier
fixed. Compensation
of the motor pole is done by an external capacitor (CAP CPC).
Both grounds GND1 and GND2 must be connected
which tranfer gain is internally
together.
ADJUSTMENTS
The system has been designed in such a way that the tolerances of the application
the approximate values of the following components must still be determined:
.The
start capacitor;
this determines
the frequency
are not critical.
However,
of the start oscillator
.The two capacitors in the adaptive commutation delay circuit. These are important
for commutation, depending on the type and loading of the motor
~ The timing capacitor;
components
in determining
the optimum
moment
this provides the system with its timing signals
(This deals with the application
note AN94070)
THE START CAPACITORS (CAP-ST)
This capacitor determines the frequency of the start oscillator. It is charged and discharged,
0.05 to 2.2 V and back to 0.05 V. The time taken to complete one cycle is given by:
tstart = (2.15 X C)s
with a current of 2 ~A, from
(with C in ~F)
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) .If the movement of the motor
generates enough EMF the TDA5240T 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:
1
'osc
November
96
= ¥
x ( Kt x I x J )2
12/19
Philips
Product specification
Semiconductors
Brushless
DC motor drive circuit
TDA5240T
where:
Kt = torque constant
(N.m/A)
I = current (A)
p = number of magnetic
pole-pairs
J = inertia J (kg/m2)
Example: J = 72 x 10---6kg/m2, K = 25 x 10-3 N.m/A, p = 6 and I = 0.5 A; this gives f osc = 5 Hz. If the damping
then a start frequency of 2 Hz can be chosen or t = 500 ms, thus C = 0.5/2 = 0.25 ~F, (choose 220 nF).
THE ADAPTIVE COMMUTATION DELAY (CAP-CDM
is high
AND CAP-CDS)
In this circuit capacitor CAP-CDM 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-CDM) is discharged at twice the charging
current. The charging current is 8.1 J.lA and the discharging current 16.2 J.lA ; 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, fc1 :
8.1
c=
If the frequency
2.2 to 0.9 Vat
-5
-~
iXT:3
is lower, then a constant commutation
(C in nF)
-fC1
delay after the zero-crossing
is generated
by the discharge
from
16.2I1A.
maximum delay = (0.076 x C) ms (witch C in nF)
Example: nominal commutation frequency = 900 Hz and the lowest usable frequency = 400 Hz, so:
CAP-CDM = ~=
15.6 (choose 18 nF)
The other capacitor, CAP-CDS, is used to repeat the same delay by charging and discharging with 20 ~.
The same value can be chosen as for CAP-CDM. Figure 7 illustrates typical voltage waveforms
I
!
ICOM
COM
I
voltoge l\
I
on CAP-DC
I ~
I
ZCR
Fig.7
COM COM I COM
I
I rr\
i
I I
I ~
I
I
ICOM
I
rT\
I ~
I
ZCR
I
I
ZCR
ZCR
CAP-CDM
and CAP-CDS
voltage
(ZCR=ZERO-CROSSING
I
ZCR
1
ZCR
waveforms
in normal
; COM=COMMUTATION)
t~
running
mode.
THE TIMING CAPACITOR(CAP- TI)
Capacitor
CAP- TI is used for timing the successive
steps within one commutation
internal delays.
.
November
96
13/19
period; these steps include some
Philips Semiconductors
Brushless
Product specification
DC motor drive circuit
TDA5240T
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,
motionless or rotating in the reverse direction, then the time can be longer ( » ms ).
if the motor is
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 I1A, from 0.2 to 0.3 V. Above this level it is charged, with a current of 5 JlA,
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 11A. The watchdog time is the time taken to
charge the capacitor, with a current of 5 JlA, from 0.3 to 2.2 V. The value of CAP- TI is given by:
= 2.63
tm (C in nF ; t in ms)
Example: If after switching off, the voltage from a motor winding is reduced, in 3.5 ms, to within 20 mV (the offset of the
EMF comparator), then the value of the required timing capacitor is given by:
C = 2.63 x 3.5 = 9.2 (choose 10 nF)
Typical voltage waveforms are illustrated by Fig. 8.
voltoge
on CAP- TI
MKAI34
If the chosen value of CAP- TI is too small, then 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).
Fig.8 Typical CAP- TI and VMOT1 voltage waveforms
.
November 96
14/19
in normal running mode.
Philips Semiconductors
Brushless
Product specification
DC motor drive circuit
TDA5240T
OTHER DESIGN ASPECTS
There are other design aspects concerning
.Generation
.Built-in
the application
of the TDA5240T
besides the commutation
function.
They are:
of the tacho signal FG
interface for a PG sensor.
.Reliability
.
FG SIGNAL
The FG signal is generated in the TDA5240T by using the zero-crossing of the motor EMF from the three motor windings.
Every zero-crossing in a (star connected) motor winding is used to toggle the FG output signal. The FG frequency is
therefore half the commutation frequency. All transitions indicate the detection of a zero-crossing
(except for PG). The
negative-going
edges are called FG pulses because they generate an interrupt in a controlling microprocessor.
The accuracy of the FG output signal Oitter) is very good. This accuracy depends on the symmetry
electromagnetic
construction, which also effects the satisfactory functioning of the motor itself.
of the motor's
Two FG frequencies are given out: 6 times the number of poles pairs or 3 times the number of poles pairs. A pull-up
resistor must be connected to PGFG outputs
Example: A three phase motor with 6 magnetic pole-pairs at 1500 rpm and with a full-wave
frequency of 25 x 6 x 6 = 900 Hz, and generates a tacho signal of 450 Hz.
drive has a commutation
PG SIGNAL
The accuracy of the PG signal in applications such as VCR must be high (phase information. This accuracy is obtained
by combining the accurate FG signal with the PG signal by using a wide tolerance external PG sensor. The external PG
signal (PGIN) is only used as an indicator to select a particular FG pulse. This pulse differs from the other FG pulses in
that a ahort LOW-time of 15 ~s after a HIGH to LOW transition. All other FG pulses have a 50% duty factor (see Fig. 9).
toleronce
PG IN
on
PG
IN
vAv
vAv
MOT3
PG/FG~~~~
~
Fig.9 Timing of the FG and PG signals
RELIABILITY
It is necessary to protect high current circuits and the output stages are protected in two ways:
November
96
15/19
Philips Semiconductors
Brushless
Product specification
DC motor drive circuit
TDA5240T
.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
when the transistor
November
96
of the six output transistors is achieved by each transistor having a thermal sensor that is active
is switched on. The transistors are switched off when the local temperature becomes too high.
16/19
~
Philips Semiconductors
Brushless
Product specification
DC motor drive circuit
TDA5240T
PACKAGE OUTliNE
0.9 (4x)
0.4
IJ
~
D
r-,OODP
20
11
1.1
~
1.0
pin1;B
2.45
0.3
2.25
0.1
2065
,
0.32
2035
-
0.23
~
-,-J
index
1.1
..,\ 0.5*
10
~
[] []
D
IJ L
D
0.49j
0.36
8
(20x)
~
Dimensions in mm
Fig.10
November
96
20-pin small-outline;
plastic (SO20L;SOT163A).
17/19
OtO8°
MBC234
Philips Semiconductors
Brushless
Product specification
DC motor drive circuit
TDA5240T
SOLDERING
Introduction
There is no soldering method that is ideal for all IC packages. Wave soldering is often preferred when through-hole and
surface mounted components are mixed on one printed-circuit board. However, wave soldering is not always suitable for
surface mounted ICs, or for printed-circuits with high population densities. In these situations reflow soldering is often
used.
This text gives a very brief insight to a complex technology.
"IC Package Databook" (order code 9398 652 90011 ).
Reflow
ICs can be found in our
soldering
Reflow soldering
.
A more in-depth account of soldering
techniques
are suitable for all sa packages.
Reflow soldering requires solder paste (a suspension of fine solder particles, flux and binding agent) to be applied to the
printed-circuit board by screen printing, stencilling or pressure-syringe
dispensing before package placement.
Several techniques exist for reflowing; for example, thermal conduction by heated belt. Dwell times vary between
50 and 300 seconds depending on heating 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 minutes at 45 °C.
Wave soldering
Wave soldering
.A
techniques
double-wave (a turbulent
should be used.
.The
longitudinal
.The
package footprint
can be used for all sa packages
if the following
wave with high upward pressure followed
axis of the package footprint
must incorporate
conditions
are observed:
by a smooth laminar wave) soldering
technique
must be parallel to the solder flow-
solder thieves at the downstream
end.
During placement and before soldering, the package must be fixed with a droplet of adhesive. The adhesive can be
applied by screen printing, pin transfer or syringe dispensing. The package can be soldered after the adhesive is cured.
Maximum permissible solder temperature is 260 oC, and maximum duration of package immersion in solder is
10 seconds, if cooled to less than 150 oC within 6 seconds. Typical dwell time is 4 seconds at 250 oC.
A mildly-activated
Repairing
flux will eliminate
soldered
the need for removal of corrosive
residues in most applications.
joints
Fix the component by first soldering two diagonally- opposite end leads. Use only a low voltage soldering iron (less
than 24 V) applied to the flat part of the lead. Contact time must be limited to 10 seconds at up to 300 °C. When using a
dedicated tool, all other leads can be soldered in one operation within 2 to 5 seconds between 270 and 320 °C.
November
96
18/19
Philips Semiconductors
Product specification
Brushless DC motor drive circuit
TDA5240T
Data sheet status
Data sheet status [1]
Product
status [2]
Definitions
Objective
specification
Development
This data sheet contains data from the objective specification for product development.
Philips Semiconductors reserves the right to change the specification in any manner without notice.
Preliminary
specification
Qualification
This data sheet contains data from the preliminary specification. Supplementary data will be
published at a later date. Philips Semiconductors reserves the right to change the specification
without notice, in order to improve the design and supply the best possible product.
Product
specification
Production
This data sheet contains data from the product specification. Philips Semiconductors reserves the
right to make changes at any time in order to improve the design, manufacturing and supply.
Changes will be communicated according to the Customer Product/Process Change Notification
(CPCN) procedure SNW-SQ-650A.
[1] Please consult the most recently issued data sheet before initiating or completing a design.
[2] The product status of the device(s) described in this data sheet may have changed since this data sheet was published. The latest information is available on the Internet at URL
http://www.semiconductors.philips.com.
Definitions
Short-form specification — The data in a short-form specification is extracted from a full data sheet with the same type number and title. For
detailed information see the relevant data sheet or data handbook.
Limiting values definition — Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 60134). 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 — Applications that are described herein for any of these products are for illustrative purposes only. Philips
Semiconductors make no representation or warranty that such applications will be suitable for the specified use without further testing or
modification.
Disclaimers
Life support — 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 Semiconductors customers using or selling these products for use in such applications
do so at their own risk and agree to fully indemnify Philips Semiconductors for any damages resulting from such application.
Right to make changes — Philips Semiconductors reserves the right to make changes, without notice, in the products, including circuits, standard
cells, and/or software, described or contained herein in order to improve design and/or performance. Philips Semiconductors assumes no
responsibility or liability for the use of any of these products, conveys no license or title under any patent, copyright, or mask work right to these
products, and makes no representations or warranties that these products are free from patent, copyright, or mask work right infringement, unless
otherwise specified.
 Koninklijke Philips Electronics N.V. 1996
All rights reserved. Printed in U.S.A.
Contact information
For additional information please visit
http://www.semiconductors.philips.com.
Fax: +31 40 27 24825
Date of release: 11-96
For sales offices addresses send e-mail to:
[email protected].
Document order number:
yyyy mmm dd
1
9397 750 08756