TEMIC U6081B

U6081B
PWM Power Control with Low Duty Cycle Switch Off
Description
U6081B is a PWM IC in bipolar technology for the
control of an N-channel power MOSFET used as a high
side switch. The IC is ideal for the use in the brightness
control (dimming) of lamps e.g., in dashboard
applications.
Features
D Pulse width modulation up to 2 kHz clock frequency
D Protection against short circuit, load dump overvoltage and reverse VS
D Interference and damage protection according to
VDE 0839 and ISO/TR 7637/1.
D Ground wire breakage protection
D Duty cycle 0 to 100%
D Output stage for power MOSFET
D Charge pump noise suppressed
Ordering Information
Extended Type Number
U6081B
Package
DIP8
Remarks
Block Diagram
VBatt
C5
VS
Rsh
5
1
6
Current monitoring
+ short circuit detection
C1
C2
47 kW
4
RC oscillator
PWM
Charge
pump
Logic
3
Output
Control input
Duty cycle
range
0/13 to 100 %
7
C3
47 nF
8
Voltage
monitoring
2
95 9752
150 W
R3
Ground
Figure 1. Block diagram with external circuit
TELEFUNKEN Semiconductors
Rev. A1, 14-Feb-97
1 (8)
U6081B
Pin Description
VS
1
8
Output
GND
2
7
2 VS
VI
3
6
Sense
Osc
4
5
Delay
Pin
1
2
3
4
5
6
7
8
Symbol
VS
GND
VI
Osc
Delay
Sense
2 VS
Output
Function
Supply voltage VS
IC ground
Control input (duty cycle)
Oscillator
Short circuit protection delay
Current sensing
Voltage doubler
Output
95 9944
Functional Description
Pin 1, Supply Voltage, Vs or VBatt
Overvoltage Detection
Stage 1:
If VBatt > 20 V occurs the external transistor will be
switched off and switched on again at VBatt < 18.5 V
(hysteresis).
Stage 2:
If VBatt > 28 V, the external transistor is switched on again
(load-dump protection). At the same time the voltage limitation of the IC is reduced from VS ≈ 26 V to VS ≈ 20 V.
This leads to a hysteresis characteristic so that the loaddump detection is switched off again only at VBatt < 23 V.
In this case the short–circuit protection is not in operation.
Undervoltage Detection
In the event of voltages of approximately VBatt < 5.0 V,
the external FET is switched off and the latch for shortcircuit detection is reset.
A hysteresis ensures that the FET is switched on again at
approximately VBatt 5.4 V.
Pin 2, GND
Ground-Wire Breakage
To protect the FET in the case of ground-wire breakage,
a 820-kW resistor between gate and source is recommended to provide proper switch-off conditions.
Pin 3, Control Input
The pulse width is controlled by means of an external
potentiometer (47 kW). The characteristic (angle of
rotation/duty cycle) is linear. The duty cycle can be varied
from 0 to 100%. To avoid inadmissibly high filament cold
currents, the dimmer is switched off at duty cycles of
approximately < 10% or is switched on only at duty
cycles of approximately > 13% (hysteresis). It is possible
to further restrict the duty cycle with the resistors R1 and
2 (8)
R2 (see figure 2). Pin 3 is protected against short-circuit
to VBatt and ground GND (VBatt 16.5 V).
x
Output Slope Control
The rise and fall time (tr, tf) of the lamp voltage can be
limited to reduce radio interference. This is done with an
integrator which controls a power MOSFET as source
follower. The slope time is controlled by an external
capacitor C4 and the oscillator current (see figure 2).
Calculation:
tf
+ t +V
tf
+ t + 12 V
C4
I osc
With VBatt = 12 V, C4 = 470 pF and Iosc = 40 mA, we thus
obtain a controlled slope of
r
Batt
470 pF
40 mA
r
+ 141 ms
A 100-W resistor in series to C4 is recomended to damp
device oscillations (see figure 2).
Pin 4, Oscillator
The oscillator determines the frequency of the output
voltage. This is defined by an external capacitor, C2. It is
charged with a constant current, I, until the upper
switching threshold is reached. A second current source
is then activated which taps a double current, 2 I, from
the charging current. The capacitor, C2, is thus discharged
by the current, I, until the lower switching threshold is
reached. The second source is then switched off again and
the procedure starts again.
Example for oscillator frequency calculation:
+V
V¦ + V
V + V
V T100
T 100
TL
S
+ (V * I
a + (V * I
a + (V * I
a
S
S
1
Batt
2
3
Batt
Batt
R 3)
S
S
S
a
a
R 3)
R 3)
1
a
2
3
where
TELEFUNKEN Semiconductors
Rev. A1, 14-Feb-97
U6081B
+ High switching threshold (100% duty cycle)
V t + High switching threshold (t 100% duty cycle)
V + Low switching threshold
V T100
T 100
TL
a1, a2 and a3 are fixed constant.
The above mentioned threshold voltages are calculated
for the following values given in the data sheet.
VBatt = 12 V, IS = 4 mA, R3 = 150 W ,
a1 = 0.7, a2 = 0.67 and a3 = 0.28.
+ (12 V * 4 mA 150 W)
V
T100
V Tt100
V TL
+ 11.4 V
+ 11.4 V
0.67
0.7
[8 V
+ 7.6 V
+2
I osc
(V T100
*V
)
TL
C2
+
+
, whereas C 2
22 nF
40 mA
and I osc
Therefore:
f
+2
40 mA
(8 V 3.2 V)
*
+2
(V Tt100
whereas
f
+2
*V
TL)
I osc
C2
)4
V Batt
C4
C4 = 470 pF
(7.6 V
* 3.2 V)
m
40 A
22 nF
Time delay, td, is as follows:
+ C @ (V * 0.7 V)ń(I * I
5
T5
ch
dis
)
+ 330 nF @ (9.8 V * 0.7 V)ń20 mA
+ 150 ms.
td
2. Current Limitation
The lamp current is limited by a control amplifier to protect the external power transistor. The voltage drop across
an external shunt resistor acts as the measured variable.
Current limitation takes place for a voltage drop of
Owing
to
the
difference
VT1 100 mV.
VT1–VT2 10 mV it is ensured that current limitation
occurs only when the short circuit detection circuit has
responded.
[
+ 189 Hz
22 nF
For a duty cycle of less than 100%, the oscillator
frequency, f, is as follows:
f
The lamp current is monitored by means of an external
shunt resistor. If the lamp current exceeds the threshold
for the short-circuit detection circuit (VT2 90 mV), the
duty cycle is switched over to 100% and the capacitor C5
is charged by a current source of 20 m A (Ich – Idis). The
external FET is switched off after the cut-off threshold
(VT5) is reached. Renewed switching on the FET is
possible only after a power-on reset. The current source,
Idis, ensures that the capacitor C5 is not charged by
parasitic currents. The capacitor C5 is discharged by Idis
to typ. 0.7 V.
With C5 = 330 nF and VT5 = 9.8 V, (Ich – Idis) = 20 mA,
we have
For a duty cycle of 100%, an oscillator frequency, f, is as
follows:
f
1. Short-Circuit Detection and Time Delay, td
td
+ 3.2 V
0.28
Pins 5 and 6, Short-Circuit Protection and
Current Sensing
[
After a power-on reset, the output is inactive for an half
oscillator cycle. During this time, the supply voltage
capacitor can be charged so that the current limitation is
guaranteed in the event of a short circuit when the IC is
switched on for the first time.
Pins 7 and 8, Charge Pump and Output
)4
12 V
470 pF
+ 185 Hz
A selection of different values of C2 and C4, provides a
range of oscillator frequency, f, from 10 to 2000 Hz.
TELEFUNKEN Semiconductors
Rev. A1, 14-Feb-97
Output, Pin 8, is suitable for controlling a power
MOSFET. During the active integration phase, the supply
current of the operational amplifier is mainly supplied by
the capacitor C3 (bootstrapping). Additionally, a trickle
charge is generated by an integrated oscillator
(f7 400 kHz) and a voltage doubler circuit. This
permits a gate voltage supply at a duty cycle of 100%.
3 (8)
U6081B
Absolute Maximum Ratings
Parameters
Junction temperature
Ambient temperature range
Storage temperature range
Symbol
Tj
Tamb
Tstg
Value
150
–40 to +110
–55 to +125
Unit
°C
°C
°C
Symbol
RthJA
Maximum
120
Unit
K/W
Thermal Resistance
Parameters
Junction ambient
Electrical Characteristics
Tamb = –40 to +110°C, VBatt = 9 to 16.5 V, (basic function is guaranteed between 6.0 V to 9.0 V) reference point is
ground, unless otherwise specified (see figure 1). All other values refer to Pin GND (Pin 2).
Parameters
Current consumption
Supply voltage
Test Conditions / Pins
Pin 1
Overvoltage detection,
stage 1
Stabilized voltage
IS = 10 mA
Pin 1
Battery undervoltage
ON
detection
OFF
Battery overvoltage detection
Pin 2
Stage 1:
– on
– off
Stage 2:
– on
– off
Stabilized voltage
IS = 30 mA
Pin 1
Short-circuit protection
Pin 6
Short-circuit current
VT1 = VS – V6
limitation
Short-circuit detection
VT2 = VS – V6
Delay timer short-circuit detection, VBatt = 12 V Pin 5
Switched off threshold
VT5 = VS – V5
Charge current
Discharge current
Capacitance current
I5 = Ich – Idis
Voltage doubler
Pin 7
Voltage
Duty cycle 100%
Oscillator frequency
Internal voltage
g limitation
I7 = 5 mA
(whichever is lower)
4 (8)
Symbol
IS
VBatt
Min
Typ
Max
6.8
25
Unit
mA
V
VZ
VBatt
24.5
4.4
4.8
5.0
5.4
27.0
5.6
6.0
V
V
VBatt
20.0
18.5
28.5
23.0
20.0
21.7
20.3
32.5
26.5
21.5
V
VZ
18.3
16.7
25.5
19.5
18.5
VT1
85
100
120
mV
VT2
VT1 – VT2
75
3
90
10
105
30
mV
mV
VT5
Ich
Idis
I5
9.5
10.1
13
9.8
23
3
20
27
mA
V7
f7
V7
V7
2 VS
280
26
VS+14
400
27.5
VS+15
520
30.0
VS+16
kHz
V
V
VBatt
V
V
V
mA
mA
TELEFUNKEN Semiconductors
Rev. A1, 14-Feb-97
U6081B
Parameters
Test Conditions / Pins
Switch-off at small duty cycles VBatt = 12 V
Pin 3
Output disabled
Output active
Hysteresis switch-on
Gate output
Pin 8
Voltage
g
Low level
VBatt = 16.5 V,
Tamb = 110°C, R3 = 150 W
High level,
duty cycle 100%
Current
V8 = Low level
V8 = High level, I7 > | I8 |
Oscillator
Frequency
Pin4
Threshold cycle
V T100
V8
High, a 1
VS
Upper
V Tt100
V8
Low, a 2
VS
Lower
V TL
a3 V
S
Oscillator current
VBatt = 12 V
Frequency tolerance
C4 open, C2 = 470 nF,
duty cycle = 50%
+
+
+
+
+
Symbol
Min
Typ
Max
V3/VS
V3/VS
DV3/VS
0.3
0.32
0.004
0.32
0.34
0.34
0.36
0.032
V8
0.35
0.70
0.95
1.5 *)
V8
1.0
–1.0
a1
f
10
0.68
0.7
2000
0.72
a2
0.65
0.67
0.69
a3
0.26
0.28
0.3
34
6.0
45
9.9
54
13.5
f
V
V7
I8
Iosc
Unit
mA
Hz
mA
Hz
*) Reference point is battery ground
TELEFUNKEN Semiconductors
Rev. A1, 14-Feb-97
5 (8)
U6081B
Package Information
Package DIP8
Dimensions in mm
7.77
7.47
9.8
9.5
1.64
1.44
4.8 max
6.4 max
0.5 min
0.58
0.48
3.3
0.36 max
9.8
8.2
2.54
7.62
8
5
technical drawings
according to DIN
specifications
13021
1
6 (8)
4
TELEFUNKEN Semiconductors
Rev. A1, 14-Feb-97
TELEFUNKEN Semiconductors
Rev. A1, 14-Feb-97
95 9759
22 nF
47 m F
C1
C2
R2
47 k W
R1
Low voltage
monitoring
VS
–
+
Reset
+
–
+
–
VS
Reset
Duty factor = 10%
Switch – on
delay
Overvoltage
monitoring
stage 1
30 k W
2I
VS
3
4
Oscillator
I
VS
100 W
–
+
Reset
–
+
VS
C5
Idis
5
150 W
Ich
VS
330 nF
VS
Ground
R3
2
+
–
Overvoltage
monitoring
stage 2
1
+
–
Current limiting
+
Voltage
doubler
8
7
6
10 mV
90 mV
VS
VS
C4
820 k W
470 pF
47 nF
Load
RL
C3
Rsh
VBatt
U6081B
Application
Figure 2.
7 (8)
U6081B
Ozone Depleting Substances Policy Statement
It is the policy of TEMIC TELEFUNKEN microelectronic GmbH to
1. Meet all present and future national and international statutory requirements.
2. Regularly and continuously improve the performance of our products, processes, distribution and operating systems
with respect to their impact on the health and safety of our employees and the public, as well as their impact on
the environment.
It is particular concern to control or eliminate releases of those substances into the atmosphere which are known as
ozone depleting substances ( ODSs).
The Montreal Protocol ( 1987) and its London Amendments ( 1990) intend to severely restrict the use of ODSs and
forbid their use within the next ten years. Various national and international initiatives are pressing for an earlier ban
on these substances.
TEMIC TELEFUNKEN microelectronic GmbH semiconductor division has been able to use its policy of
continuous improvements to eliminate the use of ODSs listed in the following documents.
1. Annex A, B and list of transitional substances of the Montreal Protocol and the London Amendments respectively
2 . Class I and II ozone depleting substances in the Clean Air Act Amendments of 1990 by the Environmental
Protection Agency ( EPA) in the USA
3. Council Decision 88/540/EEC and 91/690/EEC Annex A, B and C ( transitional substances ) respectively.
TEMIC can certify that our semiconductors are not manufactured with ozone depleting substances and do not contain
such substances.
We reserve the right to make changes to improve technical design and may do so without further notice.
Parameters can vary in different applications. All operating parameters must be validated for each customer
application by the customer. Should the buyer use TEMIC products for any unintended or unauthorized
application, the buyer shall indemnify TEMIC against all claims, costs, damages, and expenses, arising out of,
directly or indirectly, any claim of personal damage, injury or death associated with such unintended or
unauthorized use.
TEMIC TELEFUNKEN microelectronic GmbH, P.O.B. 3535, D-74025 Heilbronn, Germany
Telephone: 49 ( 0 ) 7131 67 2831, Fax number: 49 ( 0 ) 7131 67 2423
8 (8)
TELEFUNKEN Semiconductors
Rev. A1, 14-Feb-97