STMICROELECTRONICS UAA4713

UAA4713
MOTION DETECTOR INTERFACE
ADVANCE DATA
50/ 60 Hz AC SUPPLY
INPUT FOR PYROELECTRICAL SENSOR
INPUT FOR PHOTORESISTIVE SENSOR
SENSOR FILTER AMPLIFIER
PROGRAMMABLE ON-TIMER
TRIAC OUTPUT AND RELAY OUTPUT
SHORT CIRCUIT PROTECTION
LOW QUIESCENT CURRENT
TWO-WIRE TECHNIQUE
DESCRIPTION
The UAA4713 is a monolithic integrated circuit intended to control triac or relay switch for ACmains timer applications.The device can be used
in a wide range of industrial and consumer applications as light control, automatic door opening
detector, fire alarm, fluid level control .
The circuit processes the output signal of an infrared pyroelectric detector which senses temperature changes caused by heat radiation of the human body.
DIP-14
SO-14
ORDERING NUMBERS:
UAA4713DP
UAA4713FP
If the sensor detects a temperature change, a
programmable timer will start and switch a lamp
or other loads to the mains.
A further input for a photo-resistive sensor allows
to program circuit operation depending on the
day-light intensity.
Internal circuits avoid false triggering of the external actuators. (see functional diagram).
BLOCK DIAGRAM
December 1991
1/14
This is advanced information on a new product now in development or undergoing evaluation. Details are subject to change without notice.
UAA4713
FUNCTIONAL DIAGRAM
ABSOLUTE MAXIMUM RATINGS
Symbol
Test Conditions
Unit
I7
AC Supply Current
Parameter
60
mA
I7
Peak Current (T.P < 200µs)
200
mA
I7
Sourge Current (not repetitive 10ms)
500
mA
I9
ZCD Max. Input Current
5
mA
V6-3
Negative Clamp Voltage
-9
V
V8-3
Positive Clamp Voltage
9.5
V
V14-3
Comp. Input Voltage
±8
V
V10-12
Differential Input Voltage
±8
V
Top
°C
Operating Temperature
-25 to 85
Tstg,T j
Junction and Storage Temperature
-40 to 150
°C
Ptot
Total Power Dissipation (Tj = 85°C)
650
mW
THERMAL DATA
Symbol
Rth j-amb
2/14
Parameter
Thermal Resistance Junction-ambient
max
Value
Unit
100
°C/W
UAA4713
PIN CONNECTION (Top view)
PIN FUNCTIONS
Pin
Symbols
1
TCI
Time control Input
2
PRI
Photosensor comparator input
3
GND
Ground
4
ROUT
Relay output
5
TOUT
Triac output
6
V-
7
ACI
AC-input supply
8
V+
Positive clamp voltage
9
ZCD
10
NII
11
VREF
12
II
13
OP OUT
14
WCI
Functions
Negative clamp voltage
Zero cross detector
Non-invert input sensor amplifier
Sensor reference voltage
Invert input sensor amplifier
Output sensor amplifier
Window comparator input
3/14
UAA4713
ELECTRICAL CHARACTERISTICS (IS = + 2mA to +10mA;Tamb = 25°C unless otherwise specified)
Symbol
Parameter
IS
Operative Supply Current
Min.
7
±0.7
Typ.
-7
V
8.4
V
11
6
5
7.2
7.2
V
V
Output Current Relay Driver during on-time VROUT = 0V
4
80
Relay Driver Source
Saturation Voltage
IR OUT = 80µA
4
Relay Sink Output Current
VR OUT = 0.4V during on-time
Sensor Reference Voltage
IROUT
IREF = 50µA
IREF = 200µA
6.6
µA
2
4
1
ITOUT
Triac Firing Current
5
50
65
VZCD
Zero Cross Detector
Clamping Voltage
9
±7.4
±8
IZCD
Zero Cross Detector
Operating Current
9
1.6
IPRI
Photoresistor Source
Current
VPRI = 0V
2
6
Photoresistor Threshold
Voltage
IS = 0.7mA
2
3
ITCI
Timer Control Input Current
VTCI 0 to V+
tTIM
On-Timer Counter Duration
(depends on the mains
frequency and on externally
adjustable Timer Control
Input Voltage) + 1/2 cicle
precision
VTCI
8
V
mA
mA
±8.6
V
10
µA
10
14
µA
3.3
3.6
V
1
0
0.5
µA
14/4
50
60
Hz
11/12 V+
0
0
s
9/12
V+
4.48
3.73
s
7/12
V+
40
33.3
s
5/12
V+
81
67.5
s
3/12
V+
163
135.8
s
1/12
V+
327
272.5
s
0V (GND)
50Hz
tD
Delay Time Between
Window Comparator Input
and Timer Start
tDR
Delay Time Between Timer
Stop to Retrigger
ITOL
Triac Output Leakage Current VTO = 0V
Continue
14/4
60Hz
50Hz
40
50
60
ms
33.3
41.6
50
ms
14/4
500
60Hz
IWCI
mA
7.6
VREF
Vth WCI
Unit
+ 15
-7.8
Positive Clamping Voltage
VPRth
Max.
6
Negative Clamping Voltage
IR
±IS = 0.7mA
Pin
8
VV+
VR HIGH
Test Condition
Window Comparator T4
Pin 2 open
Window Comparator Input
Current
VWCI = -2V to + 2V
ms
600
5
14/4
ms
10
±1.20
±1.3
14
µA
±1.40
V
±1
mA
OP. AMP.
4/14
RI
Input Resistance
10/12
IIO
Input Offset Current
10/12
25
nA
IIB
Input Bias Current
10/12
1
µA
1
MΩ
VIO
Input Offset Voltage
10/12
- 10
+10
mV
VCM
Common Mode Volt. Renge
10/12
- 4.5
5
V
VO
Output Voltage Swing
13
±4
±5
V
IO
Output Current
13
ISC
Output Short Circuit Current
13
GV
Large Signal Open Loop
Voltage Gain
RL = 10K
1.5
mA
3
80
100
mA
V
UAA4713
Figure 1: Open Loop Frequency Response
Figure 2: VREF versus IREF
Figure 3: Supply Current
5/14
UAA4713
SYSTEM DESCRIPTION (see Functional Diagram)
If a heat source moves in front of the IR-detector,
the sensor delivers a quasi sinusoidal AC-signal
in the µV to mV range. The operational amplifier
amplifies the sensor signal by 72dB.
To reject an unwanted signal, a band pass filter is
needed. If the AC-level at pin 14 exceeds the window comparator thresholds, the programmable
timer will start. To suppress short sensor signals,
a 50ms time filter is implemented between the
window comparator output and the programmable
timer. This function improves the noise immunity.
After the reset of the timer a second timer will provide a 600ms dead time to prevent retriggering of
the timer. This function avoids restarting of the
timer, when the turned off lamp temperature. decreases
The lamp switched by the triac can be located
close to the sensor.
To avoid circuit operation during day-time, a
photo resistor (LDR) senses the light intensity and
switches off the circuit. The capacitor at pin 2 prevents circuit start-up during short shadow phases,
when a person passes by the sensor.
From the analog input pin 1 via the AD-converter
the on-time duration can be programmed in 7
Figure 4
Figure 5: Different Possible Filter Solutions
6/14
steps (see tTIM table in the electical characteristics). The timer is clocked by the mains frequency.
Two outputs for various applications are available.
Pin 5 is the trigger output for triac gate.
Pin 4 output can be used to switch a relay or
other loads.
The zero crossing detector provides the firing
pulse for the triac at the right time, shortly after
the zero crossing of the AC-signal.
The RC-network at pin 7 supplies current to the
circuit via a double wave rectification which is provided by a split power supply. Due to the capacitive energy transfer into pin 7, the circuit will also
be supplied with current if the triac is fired. A short
wire for circuit supply is not needed.
The circuit works similar to a simple two-terminal
switch and can be installed in parallel with ordinary mechanical pulse switches (fig. 4).
After a short supply connection via an external
pulse switch, the circuit timer will also start without a sensor signal.
Therefore the circuit can also be used as an ordinary light timer without the IR-moving sensor feature.
UAA4713
Figure 6: Triac Application
7/14
UAA4713
Figure 7: Relay Application
8/14
UAA4713
APPLICATION INFORMATION
1. HOW TO CHOOSE THE TRIAC ASSOCIATED
TO THE MOTION DETECTOR UAA4713
Analysis of the Triac Associated to the Motion
Detector UAA4713
Associated with the UAA4713, the Triac is defined by the driver output stage (Triac output pin
5) and the characteristics of the load.
The Triac is consequently defined by:
1) The gate sensitivity
2) The surge current capability
3) The RMS Triac current
4) The blocking voltage capability
1) The gate sensitivity
The ”Triggering gate current” is the parameter to
be taken into consideration. The I GT is given at
25°C. as a maximum value required to trigger the
Triac.
ex. BTA06-600CW = IGT max (mA) = 35mA
The UAA4713 Triac output provides a current of
65mA typical.
ITout = 65mA(Typ) = IG
In order to control the Triac properly IG should be
greater than 1.5 x IGT or
ITout > 1.5 IGT
For this reason it is suggested to use a snubberless Triac of the CW series (IGT < 35mA).
2) The surge current capability
In the Triac databook the surge current capability
of the Triac is given by the non repetitive surge
peak current:
ITSM
ex. BTA06-600CW
ITSM at TJ initial = 25°C
t = 8.3mA: 63A
t = 10ms: 60A
The choice of the Triac is defined by the following
application parameters:
a)The starting performance, and the ratio of
the nominal resistance to the cold resistance, KR
Imax > KR x Inominal x √
2
b)The thermal fast fuse behaviour during
short-circuit condition.
(I2t) (Triac) > (I2t) (fuse)
To select the ITsm (given as a minimum value) the
following table is suggested.
Mains: VAC (V)
240V
110V
Power (W)
600
1000
>1000
ITsm (min)
50
80
>100
ITsm (min)
80
120
>150
3) RMS Triac Current
The RMS Triac current ITRMS is defined by the
light power P:
ITRMS > 1. 25 x P x VAC
It depends also on the heat sink which has to limit
the junction temperature in the worse case conditions (Tamb max and ITRMS).
With the snubberless triac ITRMS ranges from 6A
to 25A.
4) Blocking Voltage Capability
The maximum blocking voltage VDRM is defined
by the mains:
Country
Mains Voltage
(V) VAC
VDRM (V)
EUROPE
240
600
USA
110
400
5) Conclusion:
Selector guide with the above parameters the optimal device selection for a given power to be
controlled is given in the following table:
LIGHT POWER
(W)
MAINS VOLTAGE VAC (V)
240
110
600
BTA 06 600 CW
BTA 08 400 CW
1,000
BTA 08 600 CW
BTA 12 400 CW
> 1,000
BTA X 600 CW
X = 10
X = 12
X = 16
BTA X 400 CW
X = 12
X = 16 (A)
Ref: High Performance Triacs that need no snubber (DSTRIACBK/1088)
9/14
UAA4713
APPLICATION INFORMATION (continued)
2. MOTION DETECTOR DEMO BOARD
Figure 8: Demo Board Diagram
10/14
This document allows the user to construct rapidly a Demo and Test Board for the UAA4713
UAA4713
APPLICATION INFORMATION (continued)
Demo Board - Part List
QTY
DEVICE
DESCRIPTION
SUPPLIER
1
UAA4713DP OR UAA4713FP
INTEGRATED CIRCUIT
SGS-THOMSON
1
BTA06-600 (240V mains)
BTA08-400 (110V mains)
TRIAC
TRIAC
SGS-THOMSON
SGS-THOMSON
1
KRX10FL or
IRA - EI00S series
SENSOR WITH FRESNEL LENS
Pyroelectic Infrared Sensor
PHILIPS COMPONENTS
MURATA
1
LDR07
PHOTORESISTOR
PHILIPS COMPONENTS
CAPACITORS
RESISTORS (0.25W)
QUANTITY
VALUE
QUANTITY
4
100µF/35V
3
VALUE
1MΩ
2
330nF
3
47kΩ
2
47nF
1
680Ω
1
4.7nF
1
1KΩ
1
68nF 400V
1
470KΩ
1
150nF 250V
1
220KΩ
1
3.3µF 35V
2 POTENTIOMETERS
500KΩ
Figure 9: Demo Board Photo IRA - E100S
11/14
UAA4713
DIP14 PACKAGE MECHANICAL DATA
mm
DIM.
MIN.
a1
0.51
B
1.39
TYP.
MAX.
MIN.
TYP.
MAX.
0.020
1.65
0.055
0.065
b
0.5
0.020
b1
0.25
0.010
D
20
0.787
E
8.5
0.335
e
2.54
0.100
e3
15.24
0.600
F
7.1
0.280
I
5.1
0.201
L
Z
12/14
inch
3.3
1.27
0.130
2.54
0.050
0.100
UAA4713
SO14 PACKAGE MECHANICAL DATA
mm
DIM.
MIN.
TYP.
A
a1
inch
MAX.
MIN.
TYP.
1.75
0.1
0.069
0.25
a2
MAX.
0.004
0.009
1.6
0.063
b
0.35
0.46
0.014
0.018
b1
0.19
0.25
0.007
0.010
C
0.5
0.020
c1
45 (typ.)
D
8.55
8.75
0.336
0.344
E
5.8
6.2
0.228
0.244
e
1.27
0.050
e3
7.62
0.300
F
3.8
4.0
0.15
0.157
L
0.4
1.27
0.016
0.050
M
S
0.68
0.027
8 (max.)
13/14
UAA4713
Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsibility for the
consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No
license is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied.
SGS-THOMSON Microelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of SGS-THOMSON Microelectronics.
 1994 SGS-THOMSON Microelectronics - All Rights Reserved
SGS-THOMSON Microelectronics GROUP OF COMPANIES
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