ETC U2482B

U2481B/ U2482B
TELEFUNKEN Semiconductors
Automotive Lamp Outage Monitor
Description
The U2481B and the U2482B multicomparator circuits
are designed to monitor automotive illumination by
sensing the voltage drop across shunt resistors. Provided
with extremely low comparator thresholds, these ICs can
be used together as a chip set to build an entire lamp
monitor system. Single operation of both circuits is also
possible.
As a special feature for brake lamp monitoring, the
U2481B contains a latch stage connected to one of its
triple comparators.
With
– 4 single comparators
– 1 double comparator and
– 2 triple comparators
each of the integrated circuits monitors up to 12 lamps
and up to 6 fuses.
All comparator stages are combined together to control
the common output stage.
Features
Benefits
Extremely low comparator thresholds of typically
3.5 mV
Extremely low threshold voltage gives low voltage
drop via shunt resistor. Power dissipation of the lamp
monitor module is minimized
Internal compensation for copper shunts
Internal compensation for voltage-dependent
bulb characteristic
Perfect EMC in conjunction with an appropriate
pc board layout
Comparator input voltage may exceed supply voltage
Internal protection measures for pulses
according to ISO TR 7637/1
ESD according to MIL-SID-883 C test method 3015.7
– Human body model:
4 kV
– Machine model:
200 V
EMI protection (TEM cell up to 100 V/m)
Applications
Both ICs can be used in any kind of vehicle with a 12 V
supply. It is sufficient to insert small resistors into the
lamp wiring and to provide the dashboard instrument
Rev. A1: 21.08.1995
cluster with a pilot lamp. These ICs increase the safety
and add comfort features.
Preliminary Information
1 (11)
U2481B/ U2482B
TELEFUNKEN Semiconductors
Block Diagram
VB
20
REFK1
IN1K1
28 Ref
K1
VS
13 mV
E1
27
19
VB
Voltage drift
of comparator
threshold
IT = f (VB)
+
–
IT
IT
VS
Power
on
Reset
Stabilized
voltage
Vstab = 5.2 V
POR
IT
Divider
REFK2
IN1K2
1
Ref K2 13 mV
2
IN1K3
IN2K3
IN3K3
INFK3
REFK4
IN1K4
INFK5
REFK5
IN1K5
IN2K5
7
REFK7
IN1K7
IN2K7
IN3K7
Cl2
Ref K3 3.5 mV
6
E1
8
9
Up down counter
T = 1.2 s
Cl2
E2
Start
High at
forward counter end
E3
26
VS
Set
Out
High at
Start
return counter zero
Reset
Cl1
24
Ref K4 3.5 mV
25
14
E1
OUT
16
4
Ref K5 3.5 mV
3
Out
E1
5
E2
10
12
13
17
POR
INFK6
Set
Ref K7
3.5 mV
3.5 mV
Cl2
E1
IN1K6
* Connection to
GND only for
U2482B (latch
disabled
High at
Start
forward counter end
Start
High at
return counter zero
E2
REFK6
21
VS
Up down counter
T = 1.2 s
E1
E3
22
K6 Ref
+
–
23
11
Reset
Latch for
stoplamps
VB
INF
OSC
E1
Cl1
REFK3
15
Oscillator
Clock 1 Clock 2
2-TOsc 20-TOsc
18
GND
*
Cl1
94 8833
Figure 1.
2 (11)
Preliminary Information
Rev. A1: 21.08.1995
U2481B/ U2482B
TELEFUNKEN Semiconductors
Pin Description
REFK2
1
28
REFK1
IN1K2
2
27
IN1K1
In1K5
3
26
INFK3
REFK5
4
25
IN1K4
IN2K5
5
24
REFK4
IN1K3
6
23
Pin
1
Symbol
REFK2
2
3
4
IN1K2
IN1K5
REFK5
5
6
7
IN2K5
IN1K3
REFK3
8
9
10
IN2K3
IN3K3
IN1K7
11
REFK7
12
IN2K7
INF
REFK3
7
22
REFK6
13
IN3K7
IN2K3
8
21
IN1K6
14
15
16
OUT
OSC
INFK5
IN3K3
9
20
VB
17
INFK6
IN1K7
10
19
VS
18
19
20
GND
VS
VB
REFK7
11
18
GND
21
22
IN1K6
REFK6
IN2K7 12
17
INFK6
23
24
INF
REFK4
IN3K7 13
16
INFK5
25
26
IN1K4
INFK3
14
15
OSC
27
28
IN1K1
REFK1
OUT
94 8831
Function
Reference for threshold voltage
single comparator K2
Input 1; single comparator K2
Input 1; double comparator K5
Reference for threshold voltage;
double comparator K5
Input 2; double comparator K5
Input 1; triple comparator K3
Reference for threshold voltage;
triple comparator K3
Input 2; triple comparator K3
Input 3; triple comparator K3
Input 1; triple comparator K7
(U2481B with latch)
Reference for threshold voltage;
triple comparator K7
(U2481B with latch)
Input 2; triple comparator K7
(U2481B with latch)
Input 3; triple comparator K7
(U2481B with latch)
Output for pilot lamp
R/C combination for oscillator
Fuse monitor input ; double
comparator K5
Fuse monitor input; single
comparator K6
Ground
Supply voltage
Reference voltage of comparators
Input1; single comparator K6
Reference for threshold voltage;
single comparator K6
Input; brake fuse comparator
Reference for threshold voltage;
single comparator K4
Input 1; single comparator K4
Fuse monitor input; triple
comparator K3
Input 1; single comparator K1
Reference for threshold voltage;
single comparator K1
Figure 2. Pin configuration
Rev. A1: 21.08.1995
Preliminary Information
3 (11)
U2481B/ U2482B
TELEFUNKEN Semiconductors
150 R1
1000 VBatt
R2
C2
0.1 F
C1
15 F
VB
20
VS
Rosc
19
82 k
28
A
1 k
Fuse
15
Osc
Cosc
27
10 nF
2 k
Pilot
lamp
1.2 W
U2481B
U2482B
2 k
16
4
14
1 k
Shunt
Out
Kl 61
3
B
2 k
Shunt
5
2 k
95 10689
Out
A: Example of a “single comparator” using the fuse as a shunt resistor
B: Example of a “double comparator” using copper shunts and additional fuse monitoring
Figure 3. Basic application diagram
4 (11)
Preliminary Information
Rev. A1: 21.08.1995
TELEFUNKEN Semiconductors
U2481B/ U2482B
Functional Description
Power Supply, Pins 19 and 20
The Ics have two supply pins. The IC itself is supplied via
Pin 19 (stabilized voltage, POR-circuitry). Pin 20
supplies only the current sources of the comparators. Both
pins have an an internal 21 V Zener Diode for protection.
For reasons of interference protection and surge
immunity the supply voltage pins have to be provided
with RC-circuitries as shown in figure... The resistors
limit the current in the case of overvoltage, whereas the
capacitors smooth the supply voltage.
Recommended values:
Pin 19:
R = 150 ;
K = 0.1 F
Pin 20:
R = 1000 ; K = 0.1 F
An external diode protects the IC against battery reversal.
Power-On-Reset
When the supply voltage is switched on, a power-on-reset
pulse is generated internally which resets the brake lamp
monitor latch and the counter stages.
Oscillator, Pin 15
The RC-oscillator is the time base for clock 1 and clock 2
(see block diagram) which are desired from a divider
stage and fed to the two upward and downward counters.
The oscillator frequency fosc is mainly determined by the
external R/C components and an integrated resistor. The
capacitor K is charged by the external resistor and
discharged by the integrated one. Because of the temperature characteristic and the tolerances of the integrated
2 k-resistor, the external one has to have considerable
higher value in order to achieve a stable frequency.
Calculation of the frequency:
f osc 1 c1 (0.74 R osc 2260 )
osc
f osc
With the recommended values
In order to disable monitoring when the lamps are
switched off, therefore the comparator outputs are
disabled if the reference voltage Vref < VMin with
VMin = 0.33VB.
As protection against transients on the supply, all
comparator inputs require external resistors. Their
tolerances directly influence the comparator threshold
accuracy. Resistors with a 1% tolerance are
recommended.
Single comparators: The inputs (K1, K2, K4, K6) sink
currents of typically 10 A each. During switch-over, the
currents of reference and input pins are identical.
Therefore identical external protection resistors
(R = 1 k) are required.
Double comparator: The reference input (K5) sinks a
current of typically 20 A; its inputs sink currents of
typically 10 A each during switch-over. Therefore the
external protection resistors must provide R = 1 k for
REFK5 and R = 2 k each for IN1K5 and IN2K5.
Triple comparators: The reference inputs (K3 and K7)
sink currents of typically 30 A. All inputs (IN1K3, IN2K3
IN3K3, and IN1K7, IN2K7, IN3K7) sink the identical typical
current of 10 A during switch-over. Therefore the
external protection resistor must provide R = 1 k for
REFK3 and REFK7 and R = 3 k at each input.
Fuse Monitoring
The internal EXOR conjunction of comparators K1 and
K2 allows fuse monitoring for both lamps. Even a
simultaneous blowout of both fuses is detected.
The pins INFK3, INFK5 and INFK6 with their EXOR gates
can be used for additional fuse monitoring.
Rosc = 82 k and Cosc = 10 nF
Detection threshold for a blown fuse is Vref < VMin with
VMin = 0.33 VB (VB = reference voltage of comparators).
fosc ≈ 1.58 kHz
Comparators
Comparators K1 and K2: threshold voltage of typically
Vth = 13 mV; designed to monitor high- and low-beam
bulbs, where the fuses can be used as shunt resistors.
Comparators K3 to K7: threshold voltage of typically
Vth = 3.5 mV; designed for all other monitor purposes.
Due to the integrated compensation circuitry, these
comparators are suitable for pc layer copper shunts.
Rev. A1: 21.08.1995
A bulb is detected as “good” as long as the voltage drop
via the shunt resistor exceeds the threshold voltage. The
pilot lamp is off. A failed bulb is detected if the voltage
drop via the shunt resistor is smaller than the threshold
voltage. The pilot lamp is on. An external transistor is
necessary to drive the pilot lamp.
Pin INF is used for brake fuse monitoring. With a voltage
drop VF > 4.8 V across the fuse, the comparator detects
a blown fuse. A voltage drop VF < 2.8 V represents a
“good” fuse. U2481B’s comparator K7 is connected to a
latch, thus a brake lamp outage is memorized.
Preliminary Information
5 (11)
U2481B/ U2482B
Integrated Delay, Debouncing, Failure Display
As soon as a comparator detects a failure a slow upward
counter is started in order to generate the delay time,
tdel = 1.2 s. With a consistent failure the output stage is
enabled after tdel. If the failure disappears during tdel a fast
downward counter is started in order to generate the reset
time treset 135 ms. The upward counter is reset, the
output stage stays disabled.
Benefits: Intermittent contacts in the wire harness do not
activate the pilot lamp! Even cyclical intermittent
contacts are screened out as long as the pulse/pause ratio
is smaller than 10:1. In the case of higher duty cycles the
upward counter may reach its trigger threshold for the
output activation after t > tdel.
Individual delay- and reset times can be adjusted with
external R/C components according to (see “oscillator”)
– tdel = 1930 x tosc
– treset = 198 x tosc
6 (11)
TELEFUNKEN Semiconductors
Latch for Brake Lamp Monitor
A failure of a brake lamp detected by comparator K7 or
a blown fuse in the brake circuitry is memorized after the
delay time has expired.
A reset of the latch can only be performed with a “poweron-reset”.
Output Stage
The output is a Darlington stage stage with protection
diodes to VS and IC ground. The output is designed to
drive an external pilot lamp with an external PNP
transistor.
At the end of the delay time the output stage is switched
on and can source a current of Iout = –10 mA with a typical
saturation voltage of Vsat = 1 V.
Test Mode
With VTEST = 23 V (20 mA) applied to Pin osc, via a
200 resistor the delay time stage can be bypassed for
test purposes. A failure detection will be displayed
immediately to save time during threshold testing.
Preliminary Information
Rev. A1: 21.08.1995
U2481B/ U2482B
TELEFUNKEN Semiconductors
Application Hints
Layout Recommendations for Copper
Layer Shunts
Lamp outage monitor systems can be produced most costefficiently if stamped shunt resistors are replaced by
copper layer shunts which are generated with the pc board
layout.
The U2481B and the U2482B are suitable for this
application because of their comparator thresholds,
which are compensated in reference to the temperature
characteristic of copper.
A constant lamp current, ILAMP = VTh/Rsh with threshold
voltage VTh = f(T) and shunt resistor Rsh = f(T), is
achieved if the comparator threshold and the shunt
resistor have identical temperature characteristics. With
the temperature coefficient of copper acu = 3.9<10–3
1/K, a copper shunt changes its nominal value by 52% if
the automotive ambient temperature range of tamb = –40
to +95°C is taken into consideration.
Two equations for calculation of the shunt resistance:
Rshunt = RA<L/Wcn
(with RA = Cu sheet resistance)
Rshunt = VTh / 1/2 ILAMP
Thus the length of copper shunt is calculated as:
L = 2<VTh<Wcn / RA<ILAMP
L = 215 mm
For a reasonable pc-layout a meander-shaped shunt
resistor is recommended. The high lamp currents may
cause hot spots at sharp edges of the copper shunts. That
may deteriorate accuracy of the measurement. Therefore
it is recommended to layout the copper shunts with
smoothed curves.
In accordance to figure...the meander may be formed by
4 straight tracks (length LS each) and 3 connecting 180°
ares (length L are each). If the mean are radius is selected
to r = Wcn the are lenght becomes Lare = p Wcn.
Thus the total lenght is
Examples for sheet resistances of copper shunts
(Tamb = 25°C):
RA = 0.5 mW/square (35.1 mm layer thickness)
RA = 0.25 mW/square (70 mm layer thickness)
L = 4 LS + 3 Lare
How to Lay Out Copper Shunts (figure 3)
L S + 1 (L * 3
4
The width of the copper trace has to be selected in
reference to a low current-effected temperature increase.
The copper trace must be capable of peak currents which
do not blow the fuse. The peak currents are specified by
the car manufacturers.
Example:
A 7.5 A fuse allows a peak current of 26 A (1 s), 15 A
(10 s) or 10 A (60 s).
The copper shunt length has to be calculated between the
two sense connections to the comparator. The connection
of the common reference input of double and triple
comparators has to be considered carefully.
= 4 LS + 3 p Wcn
With L = 215 mm the track length becomes
p
W cn)
LS = 47.8 mm
Using Fuses as Shunt Resistors
This cost saving method can be used if the following
assumptions are fulfilled:
–
–
–
Each lamp needs a dedicated fuse
The fuse socket is mounted within the monitor
module to connect the sense linesare suitable for
this monitor
task because of their comparator thresholds are
compensated for the fuse temperature coefficient
of aF = 4.1<10–3 1/K
Calculation example for a copper shunt used with a 4 W
bulb.
Calculation Example for a 55 W Bulb and a
ILAMP = 0.325 A
Failure criterion: I = 1/2<ILAMP
10 A fuse is capable of I = 13.5 A
Copper layer thickness: 70 mm
Comparator threshold voltage (U2481B, U2482B):
VTh = 3.5 mV
Measured voltage drop across the fuse: VF = 52 mV
Measured current: ILAMP = 4.2 A
Calculated resistance: RF = 12.4 mW
Selected comparatore threshold:
VTh = 1/4 VF = 13 mV (typically);
With a lamp current ILAMP < VTh/RF =< 1.05 A
the comparator detects a blown fuse.
Assumed copper width for temperature increase
DTcu < 50°C:
Wcu = 2.5 mm (13.5 A, 70 mm)
Rev. A1: 21.08.1995
7.5 A fuse:
Preliminary Information
7 (11)
U2481B/ U2482B
TELEFUNKEN Semiconductors
Wcn = 2.5 mm
to lamp
to lamp switch
LS
Larc
Wcn
R2
28
27
R1
26
25
24
23
22
21
20
19
18
17
16
15
9
10
11
12
13
14
1
2
3
4
5
6
7
8
94 8832
U2481B
U2482B
Figure 4. Design example for a copper shunt with meander shape
Absolute Maximum Ratings
Parameters
Supply voltage
Pulse current (2 ms)
Short circuit current (reversed battery)
Output current
Junction temperature
Symbol
VS, VBatt
IS
ISC
Iout
Tj
Value
16.5
1.1
170
–12
150
Unit
V
A
mA
mA
°C
Symbol
RthJA
Tamb
Tstg
Value
110
–40 to +100
–55 to +125
Unit
K/W
°C
°C
Thermal Resistance
Parameters
Thermal resistance
Ambient temperature range
Storage temperature range
8 (11)
SO 28
Preliminary Information
Rev. A1: 21.08.1995
U2481B/ U2482B
TELEFUNKEN Semiconductors
Electrical Characteristics
Tamb = –40 to +100_C, VBatt (Kl. 15) = 10 to 15 V, supply series resistors and input protection rsistors connected (see
figure 1 “block diagram” and figure 2 “basic application schematic”) unless otherwise specified.
Parameters
Supply
Operating voltage
Supply current
Power on reset (POR)
Comparators
Comparator input current
during switch over
Comparator thresholds VT1
of comparators K1 and K2
(VT1 = VRef... – VIN...)
Voltage characteristic
Temperature characteristic
Comparator thresholds VT2
of comparators K3 to K7
(VT2 = VRef... – VIN...)
Test Conditions / Pins
Rev. A1: 21.08.1995
Min.
VBatt
9
VBatt = 13 V, V14 = low
Pin 20
Pin 19
Tamb = 25°C
Pin 19
VBatt (Kl. 15)
VBatt = 13 V
Pins 27, 28
Pins 1, 2
Pins 24, 25
Pins 21, 22
Pin 7
Pins 6, 8, 9
Pin 11
Pins 10–12
Pin 4
Pins 3,5
VS = 10 V Pins 1, 2, 27, 28
VS = 13 V
VS = 15 V
0.3
3
3.0
3.7
I27, I28
I 1 , I2
I24, I25
I21, I22
I7
I 6 , I8 , I9
I11
I10,I11,I12
I4
I 3 , I5
VT1x
x = Pin No.
8.5
10.0
11.0
DVT1
DTT1
Typ.
0.7
5
10
10
10
10
30
10
30
10
20
10
11.5
13.0
14.0
0.5
3900
Max.
Unit
16
V
1.1
7
4.2
5.0
mA
mA
V
V
mA
14.5
16.0
17.0
mV
mV/V
ppm/°K
Pins 6, 7, 8, 9
Pins 24, 25
Pins 3, 4, 5
Pins 21, 22
Pins 10, 11, 12
VS = 10 V
VS = 13 V
VS = 15 V
Voltage characteristic
Temperature characteristic
Min. comparator input
voltage for detection
Output
Output current
Output saturation voltage
Symbol
VT1x
x = Pin No.
DVT2
DTT2
VMin
all Ref-pins
VBatt = 13 V
Iout = –10 mA
Pin 19–Pin 14
1.5
2.0
2.3
Pin 14
I14
VSat
Preliminary Information
3.0
3.5
3.8
0.17
3900
0.33
VBatt
–10.0
1.0
4.5
5.0
5.3
mV
mV/V
ppm/°K
1.5
mA
V
9 (11)
U2481B/ U2482B
Parameters
Protection
Voltage of Zener diodes
Oscillator
Oscillator frequency
Delay time
Debounce time
Break fuse
Brake fuse detection
threshold
Input current
Trigger threshold (internal
pull down resistor)
Input current
Test
Test voltage for delay time
override
TELEFUNKEN Semiconductors
Test Conditions / Pins
Pin 19
Pin 20
all Ref... and IN... pins
Rosc = 82 k,
Cosc = 10 nF,
Rosc = 82 k,
Cosc = 10 nF
Rosc = 82 k,
Cosc = 10 nF
Min.
VS
VB
21
19
VRef...,
VIN...
19
fosc
1.58
Max.
Unit
V
kHz
Pin 15
1.1
1.2
1.3
s
tdb
115
125
135
ms
Pin 23
VTB
2.8
3.8
4.8
V
Pin 23
Pins 16, 17, 28
I23
VTTx
A
V
I
100
0.33
VBatt
100
V15
23
V
x=16,17,18
VBatt = 13 V
I = 20 mA
Typ.
td
VBatt
V23 = 13 V
Symbol
Pin 15
A
Dimensions in mm
Package: SO 28
95 9932
10 (11)
Preliminary Information
Rev. A1: 21.08.1995
TELEFUNKEN Semiconductors
U2481B/ U2482B
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
Rev. A1: 21.08.1995
Preliminary Information
11 (11)