IL33197A

TECHNICAL DATA
Automotive Wash Wiper Timer
The IL33197A is a standard wiper timer control device designed for harsh
automotive applications. The device can perform the intermittent, after
wash, and continuous wiper timer functions. It is designed to directly drive
a wiper motor relay. The IL33197A requires very few external
components for full system implementation. The intermittent control pin
can be switched to ground or Vbat to meet a large variety of possible
applications. The intermittent timing can be fixed or adjustable via an
external resistor. The IL33197A is built using bipolar technology and
parametrically specified over the automotive ambient temperature range
and 8.0 to 16 V supply voltage. The IL33197A can operate in both front
and rear wiper applications.
• Adjustable Time Interval of Less Than 500 ms to More Than 30 s
• Intermittent Control Pin Can Be Switched to Ground or Vbat
• Adjustable After Wipe Time
• Priority to Continuous Wipe
• Minimum Number of Timing Components
• Integrated Relay Driver With Free Wheeling Protection Diode
• Operating Voltage Range From 8.0 to 16 V
• For Front Wiper and Rear Wiper Window Applications
IL33197A
ORDERING INFORMATION
IL33197AN
DIP
IL33197AN-01
DIP
IL33197AD
SOIC
IL33197AD-01
SOIC
TA = -45 to 105C (SOIC)
TA = -45 to 125C (DIP)
* Stresses beyond those listed under “absolute maximum ratings” may
cause permanent damage to the device.
These are stress ratings only and functional operation of the device at
these or any other conditions beyond those indicated under
“recommended operating conditions” is not implied.
Exposure to absolute-maximum-rated conditions for extended periods
may affect device reliability.
January, 2011, Ver.01
IL33197A
Representative Block Diagram
This device contains 390 active transistors.
ELECTRICAL CHARACTERISTICS (–45°C 3 TA  +125°C, 8.0 V  VCC  16 V, unless otherwise noted. Typical
values reflect approximate mean at TA = 25°C with VCC = 14 V at the time of initial device characterization.)
NOTES: 1. The oscillator frequency is defined by the current flowing through the external resistor R2. The voltage at the INT pin is
(VCC/2 – Vbe) and hence the current flowing through R3 is different if R3 is connected to Vbb or to Gnd because of the
voltage drop across resistor R1. This voltage drop causes the oscillator coefficient for tb2 to be different for the two cases of
INT terminated to Gnd or to Vbb. Because of this, the oscillator coefficient is specified with a specific value of R1
whenever INT is connected to Vbb. If R1 is changed, the coefficient will change. Also, any extra current through the
resistor R1 other than the current used by the device will cause timing deviations in t b2 timings (as in the case where two
devices are sharing a common R1 resistor).
2. The oscillator stability with temperature is dependent on the temperature coefficients of the external components. If the
capacitance value of the external capacitor varies more than 5% over the parametric temperature range, the figures quoted
for oscillator variation are not valid.
3. The tb1 duration is given by coefficient 4 x R2 x C2 (t b1 duration = tb1 x 4 x R2 x C2).
4. The tb2 duration is given by coefficient x R3 x C2 (t b2 duration = tb2 x R3 x C2).
January, 2011, Ver.01
IL33197A
Figure 1. Intermittent Wash Wiper Typical Application
This application shows the IL33197A with the external wirings and two speed
wiper motor. This application has the Intermittent and Wash Wiper functions.
INTRODUCTION
The IL33197A is a wiper timer control device designed for use in harsh automotive applications. The device can perform
the intermittent, after wash, and continuous wiper timer functions. The IL33197A is designed to directly drive a wiper
motor relay. The IL33197A is suitable for both front and rear wiper applications. The IL33197A connects directly to the
vehicle’s battery voltage (Vbat) through a 220
F de–coupling filter capacitor. The device has an
internal oscillator controlled by one of two external resistors (R2 and R3) in addition to one external capacitor (C2),
dependent on the application function required. The values of C2 and R2 determine the tb1 time base. Tb1 is used to
generate the relay wiper activation during the INT function (T3) and the after wash timing (T2) during the wash wipe mode.
The values C2 and R3 determine the tb2 time base. The tb2 time base is used to generate the pause or intermittent time (T4).
The intermittent wiper function can generate intermittent timing (T4) from less than 500 ms to more than 30 seconds. The
intermittent function of the device can be activated by the INT input connected to either ground or Vbat. The intermittent
timing is externally adjustable by changing the value of resistor R3. The wash wiper timer function detects the water pump
motor’s operation. When the pump motor activation is detected, the IL33197A turns the wiper on for the entire duration of
the pump motor’s activation. When the motor is turned off, it generates an after wash timing (T2) to maintain the wiping
action. The W/W pin is connected to the water pump motor through a protection resistor (R4). The IL33197A also has a
continuous function, which activates the wiper relay whenever the CONT input is activated. The CONT input is connected
to a switch through a protection resistor (R5). The CONT input comparator has an input threshold of Vbb/2 with hysteresis.
The device has internal debounce circuitry, based on the oscillator period. This provides filtering of the intermittent (INT)
and wash wipe (W/W) input signals (see T1 Debounce Timing paragraph that follows). The device directly drives the wiper
motor relay. It internally incorporates a 20 V free wheeling zener diode to protect the device against overvoltage spikes
produced when relay is switched off.
Intermittent Operation
Conditions:
d to ground.
In this configuration, the circuit will respond to the switching of INT to either Vbb or ground after a time T1
(see T1 Debounce Timing). If INT is disconnected before the end of T1; no action will be taken. After a time T1, the
output will be switched on for a duration, T3 = 16 x 4 x tb1 and then switched off for a duration, T4 = 144 x 4 x tb2.
This sequence will continue to repeat so long as INT is disconnected from Vbb or ground for a time duration greater
than T1. If INT is disconnected during the time T3; the output will remain on for the remainder of T3. This is illustrated
in the diagram on Figure 2.
January, 2011, Ver.01
IL33197A
Wash Wipe Operation
Conditions:
In this condition, the circuit will respond to the switching of W/W to Vbb after a time T1 (see T1 Debounce
Timing). If W/W is disconnected or connected to ground before the end of T1; no action will be taken. After a time T1;
the circuit will perform as shown on Figure 3. The output will turn on and remain on for the duration of W/W. When
W/W becomes inactive, the output will remain on for T2 = 96 x 4 x tb1.
Continuous Operation
In this condition, the circuit responds to the switching of CONT to Vbb. If CONT is connected to Vbb, the output
will turn on regardless of the state of any other input and remain on so long as CONT is active. This command operates
directly on the relay output and does not interfere with any other timing. Therefore, the circuit will not be reset to a
defined state.
Wash Wiper and Intermittent Operation
If W/W is activated during the time INT is also activated, the circuit will respond to W/W after a time T1 (see T1
Debounce Timing). The output will turn on after T1, and stay on for a time T2 + T3 after W/W is deactivated.
Following this, normal operation of INT will occur. This is shown on Figure 4.
January, 2011, Ver.01
IL33197A
Figure 4. Switching Waveform W/W and INT Active
T1 Debounce Timing
The criteria for an input signal to be detected is that it should be active at two successive negative internal clock edges.
The inputs are sampled on the negative edge of the internal clock. If two consecutive samples are the same, the input is
detected as being in that state. Hence the time T1 from a signal becoming active to the time that the circuit responds can
be anytime from 4 x tb1 to 2 x 4 x tb1 (due to synchronizing the input to the oscillator period) when the oscillator is
oscillating with a time base of tb1 and 4 x tb2 to 2 x 4 x tb2, when the oscillator is oscillating with a time base of tb2.
The following table summarizes all T1 debounce timings:
Condition
INT Active
INT Inactive
W/W Active When INT Inactive
W/W Active When INT Active During T3
W/W Active When INT Active During T4
Debounce Time
4 x tb1 to 2 x 4 x tb1
4 x tb1 to 2 x 4 x tb1
4 x tb1 to 2 x 4 x tb1
4 x tb1 to 2 x 4 x tb1
4 x tb1 to 2 x 4 x tb2
Two IL33197A Devices Using One Decoupling Resistor and Capacitor
Two devices may be connected to the power source using a common R1 resistor for protection against overvoltages. If
this is done it should be noted that the current flowing through R1 is increased and hence the voltage drop across
R1 is increased.
Overvoltage Protection
In reference to the Block Diagram and Typical Application, all of the foregoing operational cases require:
, C1 F
, R4
, R5

The circuit will not operate during the transient conditions. By using the above component values, the circuit will
be able to sustain the following overvoltages on Vbb without permanent damage:
1. +28 V for 5 minutes
2. –15 V for 5 minutes
3. –16 V cycled off for 1.0 minute
4. +80 V pulse decaying exponentially to 8.0 V in 400 ms repeated 3 times at 1.0 minute intervals.
5. 
of 1.0 Joule.
6. 100 V pulse decaying exponentially to 10 V in 2 ms.
R1 
R3
January, 2011, Ver.01
IL33197A
Recommended External Component Values
Below are the recommended component values to ensure the device will operate properly, and that all specified
parameters will stay within their tolerances. R1 should be greater than 100; recommended value of 220. R1 can be
up to 500, but in this case the tb2v parameter could be out of it’s specified value (see Electrical Characteristics and
Note 1). Also, the minimum operating voltage range should be greater than 8.0 V. The following values should be
adhered to:
10 k 

1.5 k 


R4 



C1
47 nF  
Application Information
The following is an example of timing calculations using the following external components values:
R2 = 22 k, R3 = 2.2 k, C2 = 100 nF (Referring to Block Diagram and Typical Application).
Oscillator Time Base Calculation:
tb1 duration = tb1 × 4 × R2 × C2 = 1 × 4 × 27e3 × 100e–9 = 10.8 ms
tb2 duration_g (INT to Gnd) = tb2g × R3 × C2 = 15.5 × 2.2e3× 100e–9 = 3.41 ms
tb2 duration_v (INT to Vbb) = tb2v × R3 × C2 = 12.1 × 2.2e3× 100e–9 = 2.66 ms
Intermittent timing calculation:
T3 = 16 × 4 × tb1 duration = 16 × 4 × 10.8 ms = 691 ms
T4 = 144 × 4 × tb2 duration_g = 144 × 4 × 3.41 ms = 1.96 s
(INT connected to Gnd)
T4 = 144 × 4 × tb2 duration_v = 144 × 4 × 2.66 ms = 1.53 s
(INT connected to Vbb)
Wash wipe timing calculation:
T2 = 96 × 4 × tb1 = 96 × 4 × 10.8 ms = 4.15 s
T1 Debounce Time Calculation (see T1 Debounce Timing)
When oscillator is oscillating at tb1:
T1 minimum = 4 × tb1 = 4 × 10.8 ms = 43.2 ms
T1 maximum = 2 × 4 × tb1 = 2 × 4 × 10.8 ms = 86.4 ms
When oscillator is oscillating at tb2:
T1 minimum (INT connected to Gnd, tb2g) = 4 × tb2 = 4 ×3.41 ms = 13.6 ms
T1 maximum (INT connected to Gnd, tb2g) = 2 × 4 × tb2 = 2 × 4 × 3.41 ms = 27.3 ms
January, 2011, Ver.01
IL33197A
N SUFFIX PLASTIC DIP
(MS – 001BA)
A
Dimension, mm
5
8
B
1
4
F
Symbol
MIN
MAX
A
8.51
10.16
B
6.1
7.11
C
L
C
5.33
D
0.36
0.56
F
1.14
1.78
-T- SEATING
PLANE
N
G
M
K
0.25 (0.010) M
J
H
D
T
NOTES:
1. Dimensions “A”, “B” do not include mold flash or protrusions.
Maximum mold flash or protrusions 0.25 mm (0.010) per side.
G
2.54
H
7.62
J
0°
10°
K
2.92
3.81
L
7.62
8.26
M
0.2
0.36
N
0.38
D SUFFIX SOIC
(MS - 012AA)
Dimension, mm
A
8
5
B
H
1
G
P
4
D
K
MIN
MAX
A
4.8
5
B
3.8
4
C
1.35
1.75
D
0.33
0.51
F
0.4
1.27
R x 45
C
-T-
Symbol
SEATING
PLANE
J
F
0.25 (0.010) M T C M
NOTES:
1. Dimensions A and B do not include mold flash or protrusion.
2. Maximum mold flash or protrusion 0.15 mm (0.006) per side
for A; for B ‑ 0.25 mm (0.010) per side.
M
G
1.27
H
5.72
J
0°
8°
K
0.1
0.25
M
0.19
0.25
P
5.8
6.2
R
0.25
0.5
January, 2011, Ver.01