TEMIC U2102B

U2102B
Multifunction Timer
Description
The monolithic integrated bipolar circuit U2102B is an
MOSFET or IGBT control circuit which allows
realization of an extremely wide range of timer and
dimmer functions. The integrated current monitoring
function additionally permits the power switch to be
reliably protected without an additional fuse.
Features
D Adjustable and retriggerable tracking time
D External window adjustment for sensor input
D Enable input for triggering
D Integrated reverse phase control
D Two- or three-wire applications
D Mode selection:
– Zero-voltage switch with static output
– Two-stage reverse phase control with switch-off
– Two-stage reverse phase control
D Current monitoring:
– High-speed short-circuit monitoring with output
– High-current monitoring with integrating buffer
D Integrated chip temperature monitoring
Applications
D
D
D
D
D
Motion detectors
Time-delay relays
Dimmers
Reverse phase controls
Timers
Package: DIP16, SO16
94 8666
1
16
Voltage monitoring
VRef
2
3
4
5
Synchronization
15
Reverse
phase
control
Voltage limitation
Control
RC oscillator
14
Push
pull
Divider
logic
13
12
6
Current monitoring
Programing
Triggering with buffers
7
8
Temperature
monitoring
11
Test logic
10
9
Figure 1. Block diagram
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
1 (16)
2 (16)
Trigger
signal
1 mF
CRef
R2
Enable
+ VS
C2
220 nF
100kW
22 k W
1 MW
2
GND
VRef
Control
R3
8
–
+
–
+
GND
0.1/0.4/
0.5 x VRef
7
Stat. ZVS
0.45 x VRef – 0.2 x V9
Trigger window
0.55 x VRef + 0.2 V9
Enable
Voltage
monitoring
Divider
Control
Phase
Buffer
(spikefilter)
logic
Control
Clock
generator
Reverse
Clock
1 kW
Test mode
2 stage
+ VS 2 stage / out
VRef
RC oscillator
–
+
Ramp
VRef
0.02xVRef
6
5
4
820 k W 3
C3
10 nF
1
Push pull
Clock
Clock
–
Test logic
–
+
+
Window
adjustment
Buffer
120 ms
Current monitoring
POR
Q Q
R S
Temp
monitoring
Voltage
limitation
Synchronization
9
10
100 mV
11
500 mV
12
GND
13
14
15
+Vs
16
C1
100 W
RG
47 mF/25 V
68 k W
R1
33 k W / 2 W
NTC
VRef
1 nF
1 kW
Rsh
IGBT
Load
Vmains
230 V
X
94 8220 e
U2102B
Figure 2. Block diagram with typical circuit for dc loads
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
U2102B
Pin Description
Pin
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Symbol
VRef
CRamp
RRamp
Control
Osc
Prog.
EN
Trigger
V9
Test
II
Ioff
GND
VO
+ VS
Sync
Function
Reference voltage 5 V
Ramp, capacitance
Current setting for ramp
Control voltage
RC oscillator
Tri state programing
Enable-input
Trigger-input (window)
Window-adjustment
Test output
Input current monitoring
Fast output current monitoring
Ground
Output voltage
Supply voltage
Synchronization input
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
VRef 1
16 Sync
CRamp 2
15 +VS
RRamp 3
14 VO
Control 4
13 GND
Osc 5
12
Ioff
Prog. 6
11
II
EN 7
10 Test
Trigger 8
9
V9
94 8619
3 (16)
U2102B
Power Supply, Synchronization Pins 15 and 16
The voltage limitation circuit contained in the U2102B
enables simple power supply via a dropping resistor R1.
In the case of dc loads, practically all the supply current
flows into Pin 16 (the pull down resistor at Pin 16 is necessary in order to guarantee reliable synchronization) and
is supplied via an internal diode to Pin 15, where the resultant supply voltage is limited and smoothed by C1. As a
result, the rectified and divided line voltage appears at
Pin 16, where the amplitude is limited. The power supply
for the circuit can be realized in all modes for dc loads as
shown in figure 3. The voltage at Pin 16 is used to
synchronize the circuit with the mains and generate the
system clock required for the buffers. The circuit detects
a “zero crossing” when the voltage at Pin 16 falls below
an internal threshold of approximately 8 V.
Vmains
R1=Rsync
Sync.
16
+VS
Load
15
Voltage
limitation
C1
Push
pull
14
IGBT
RG
Temp.
monit.
Rsh
GND
13
95 9882
Figure 3. Power supply for dc loads (R1 is identical with Rsync)
R1 is calculated here as follows:
V Nmin –V S
R 1max
0.85
(1)
I tot
+
where:
VNmin =
Vmains – 15%
VS
Supply voltage
4 (16)
=
Itot
=
ISmax + Ix
ISmax
=
Max. current consumption of the IC
Ix
=
Current consumption of the external
components
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
U2102B
In the case of ac loads, it is necessary to make a distinction
for power supply purposes between the individual
operating modes. In reverse phase control mode, figure 4,
Pin 15 must be additionally supplied with power via a
dropping resistor, since no current flows in Pin 16 when
the power switch is switched on. Here, the dropping
resistor, R1, is connected before the rectifier bridge and
therefore has only one mains half-wave. R1 is then calculated as follows:
R 1max
+ 0.85 @ V2 @ I–V
Nmin
Load
Rsync
Sync.
S
tot
Vmains
D1
16
R1
+VS
Figure 4.
Power supply in reverse phase
control mode for ac loads
15
Voltage
limitation
C1
Push
pull
IGBT
14
RG
Temp.
monit.
Rsh
GND
13
95 9883
In two-wire systems, the additional power supply at
Pin 15 is not possible (see figure 4, by omitting R1 and
Diode D1). In this case, the resistor Rsync is identical with
R1 and should be as low as the power dissipation allows
it. A sufficiently large residual phase angle must remain
in this case in order to guarantee the device supply.
The power supply is simplified if the device is operated
as a static zero-voltage switch for ac loads (see figure 5).
All delay times are twice as long here, since synchronization of the module is tapped before the rectifier
bridge.
Load
Vmains
R1= Rsync
Sync.
16
+VS
Figure 5.
Power supply as static zero
voltage switch for ac loads
15
Voltage
limitation
C1
Push
pull
14
Temp.
monit.
IGBT
RG
Rsh
GND
13
95 9884
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
5 (16)
U2102B
Voltage Monitoring
Reverse Phase Control, Pins 2, 3, 4
While the operating voltage is being built up or reduced,
uncontrolled conditions or output pulses of insufficient
amplitude are being suppressed by the internal monitoring circuit. All latches in the circuit, the divider and the
control logic are reset. When the supply voltage is
applied, the enable threshold (clamp voltage) of approximately 16 V must be reached so that the circuit is enabled.
The circuit is reset at approximately 11 V if the supply
voltage breaks down. A further threshold is activated in
reverse phase control mode. If the supply voltage breaks
down here after enabling of the circuit, the output stage
is switched off at approximately 12.5 V, while the other
parts of the circuit are not affected. The output stage can
then be switched on again only in the following halfwave. As a result, the residual phase angle remains just
large enough, (e.g., in two-wire systems), so that the
circuit can still be properly supplied with power. In all
operating modes, a single operating cycle is started after
the supply voltage is applied, independently of the trigger
inputs, in order to immediately demonstrate the overall
function.
In the case of normal phase controls, e.g., with a triac, the
load current is switched ON only at a certain phase angle
after the zero crossing of the mains voltage. In the
following zero crossing of the current, the triac gets extinguished (switched-off) automatically. Reverse phase
control differs from this in that the load current is always
switched-on by a semiconductor switch (e.g., IBGT) at
the zero crossing of the mains voltage and then switched
back off again after a certain phase angle a. This has the
advantage that the load current always rises with the
mains voltage in a defined manner and thus keeps the
required interference suppression to a minimum.
Chip Temperature Monitoring
The circuit possesses an integrated chip temperature
monitoring circuit which disables the output stage when
a temperature of approximately 140°C is reached. The
circuit is enabled again only after cooling down and additionally switched “off and on” of the operating voltage.
The charging current for the capacitor C3 at Pin 2 is set
with the resistor R3 at Pin 3. When the synchronization
circuit recognizes a zero crossing, an increased charging
4 I3 is enabled which then charges C3 up
current I2
to 0.45 V. The output stage is switched-on at this value
and the charging current for C3 is reduced to I2 = I3. Since
the actual zero crossing of the supply voltage occurs later
than recognized by the circuit, the load current starts to
flow quite close to the exact zero crossing of the supply
voltage. While the output stage is switched-on C3 is
charged until the control voltage, set externally at Pin 4,
is reached. When this condition is reached, the output
stage is switched off and C3 is charged again with the
increased current (I2 = 4 I3) to V2 5.5 V. The
charging current is switched off at this point and C3 is
discharged internally. The whole process then starts again
when the circuit recognizes another zero crossing (see
figure 6).
[
[
[
Vmains
t
V2
1.1 VRef
V4
0.09 VRef
t
V14
t
94 8290 e
Figure 6. Signal characteristics of reverse phase control
6 (16)
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
U2102B
Programing, Pin 6
Three operating modes can be programed with the tristate
input Pin 6:
D Zero-voltage switch (ZVS)with static output
(V6 = V1 = VRef):
The reverse phase control is inactive here. The output
stage is statically switched-on after triggering by the
timer and switched-off again after the running down
of the time (at the zero crossing of the supply voltage
in each case). This operating mode is not possible in
two–wire systems.
D Two-stage reverse phase control with switch-off
( V6 = V15 = VS):
The maximum current flow angle, amax, is set when
the timer has enabled the output stage. Switchover to
the phase angle a, which can be set arbitrarily at Pin 4,
takes place after expiry of 3/4 of the tracking time set
at Pin 5. The output stage switches off after expiry of
the whole tracking time.
D Two-stage reverse phase control ( V6 = V13 = GND):
The output stage switches to the maximum current
flow angle, amax, (adjustable) if the trigger condition
for both inputs (Pins 7, 8) is satisfied. Switchover to
the current flow angle, a, set at Pin 4 takes place after
expiry of 3/4 of the tracking time set at Pin 5. The
whole process is repeated from the beginning again if
renewed triggering takes place at Pin 8. The lamp is
switched-off in the following half-wave of the mains
voltage if the trigger condition at Pin 7 disappears. In
this mode, the output stage is switched-on even if only
Pin 7 is in the ON state. The current flow angle is then
determined by V4 (e.g., house no. illumination,
twilight switch).
This threshold is approximately 2 V in switched-off
condition and also during the second current flow angle,
aain two-stage reverse phase control mode. Otherwise,
the blocking-or switch-off threshold is 0.5 V.
The input Pin 8 is designed as a window discriminator, its
window is set at Pin 9. The minimum window of approximately 250 mV is set with V9 = V13, and the maximum
window of approximately 1.25 V with V9 = Vl. The
window discriminator is in the OFF state when the
voltage at Pin 8 lies within the window set at Pin 9.
If a resistor divider with an NTC resistor is connected to
Pin 9, for example, it is possible to compensate for the
temperature dependence of the IR sensor, i.e. the range is
made independent of temperature.
Noise suppression for tON = 40 ms guarantees that there
is no peak noise signals at the inputs which could trigger
the circuit. Equally, renewed triggering is prevented for
tOFF = 640 ms after load switch-off in order to avoid any
self interference.
V7
VRef
ON
0.5 VRef
Hysteresis
0.1/0.4 VRef
OFF
0
94 8291 e
Figure 7. Trigger condition Pin 7
Trigger Inputs, Pins 7 and 8
The trigger condition of the timer is determined by the
two inputs Pins 7 and 8. A Light Dependent Resistor
( LDR) can be connected to Pin 7, for example, and an IR
sensor to Pin 8. Both inputs must be in the ON state to
initiate triggering, since they are equal and AND-gated.
In the operating mode “2-stage reverse phase control”,
the output stage can additionally be switched-on and
switched-off by Pin 7 alone and independently of the
timer.
The enable input Pin 7 is implemented as a comparator
with hysteresis. The enable threshold is approximately
2.5 V. The blocking threshold is switched by the control
logic in order to avoid faults as a result of load switching.
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
V8
VRef
ON
0.5 VRef
0.05 VRef + 0.2 V9
OFF
0.05 VRef + 0.2 V9
ON
0
94 8292 e
Figure 8. Trigger condition Pin 8
7 (16)
U2102B
RC Oscillator, Pin 5
Current Monitoring, Pins 11 and 12
An internal RC oscillator with following divider stage
1:211 permits a very long and reproducible tracking time.
The current monitoring circuit integrated in the U2102B
represents a double electronic fuse. The circuit measures
the current flowing through the power switch by way of
the voltage drop across the shunt resistor Rsh. This voltage
is supplied to Pin 11. If this voltage exceeds a value of
500 mV because of a high load current (e.g., shortcircuit), the switch-off latch is set and the switching
output Pin 11 closes immediately. Pin 11 can be
connected to the gate via a resistor or network, depending
on load conditions, thus allowing the switch-off behavior
to be adapted to the respective requirements. The shortcircuit current is reduced to a problem-free value by this
procedure.
The RC values for a certain tracking time, tt, are calculated as follows:
R 2 (kW)
+ 1.4
t t(s) 10 3
2048 C 2 (mF)
C 2 (mF)
+ 1.4
t t(s) 10 3
2048 R 2 (kW)
In reverse phase control mode, switchover from maximum current flow angle to the value set at Pin 4 takes
place after expiry of 3/4 of the total tracking time tt.
8 (16)
There is a second threshold at 100 mV. The output stage
is disabled if the voltage at Pin 11 exceeds this value and
if it reaches this value for 120 ms in every half-wave
without exceeding the switch-off threshold of 500 mV.
Since high voltage peaks would be caused by switching
off due to the line and leakage inductances, the output
stage is not switched-off immediately but is simply not
enabled in the next half-wave. The circuit is designed so
that it also switches off in the case of changing overcurrents which do not occur in every half-wave. But in
this case the switch-off time is larger.
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
U2102B
Absolute Maximum Ratings
Reference point Pin 13, unless otherwise specified
Parameters
Power supply
Current
Synchronization
Input current
t < 10 ms
v
t 10 ms
Reference voltage source
Output current
Push-pull output stage
Output current
t 2 ms
v
Input currents
Input voltages
Symbol
Value
Unit
Pin 15
IS
is
20
60
mA
Pin 16
II
ii
20
60
mA
Pin 1
– IRef
10
mA
Pin 14
Pin 14
"I
"i
10
60
mA
Pin 2
Pin 2
Pin 3
Pin 10
Pin 12
Pins 4, 5, 7, 8, 9 and 11
Pins 6 and 12
Storage temperature range
Junction temperature
Ambient temperature
O
o
–II
II
–II
II
II
VI
VI
Tstg
Tj
Tamb
0 V to V1
0V to V15
– 40 to + 125
+ 125
– 10 to + 100
°C
°C
°C
Symbol
Value
Unit
RthJA
120
180
100
K/W
"
1
8
0.2
1
20
mA
Thermal Resistance
Parameters
Junction ambient
DIP 16
SO 16 on PC board
SO 16 on ceramic
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
9 (16)
U2102B
Electrical Characteristics
VS = 15.0 V, fmains = 50 Hz, Tamb = 25°C, reference point Pin 13, unless otherwise specified
Parameters
Supply voltage limitation
Current consumption
Voltage monitoring
Switch-on threshold
Switch-off threshold
Undervoltage threshold
Reference voltage
Synchronization
Voltage limitation
Input current
Zero crossing switch-on threshold
Zero crossing switch-off threshold
Reverse phase control
Ramp current setting
Input current
Input voltage
Ramp
Charging current 1
Charging current 2
Discharge impedance
Switch-on threshold, output stage
Discharge threshold voltage
Control voltage
Input voltage
Input current
Programing, tri state input
Input current
Operating mode:
Static zero-voltage switch
2-stage reverse phase control with
it h ff
switch-off
2-stage reverse phase control
RC oscillator
Input current
Upper threshold
Lower threshold
Discharge impedance
10 (16)
Test Conditions / Pin
Symbol
IS = 2 mA
Pin 15
VS
VS
IS = 5 mA
VS = 15 V
Pin 15
IS
Pin 15
VSON
VSOFF
V15
– I1 = 0 to 5 mA
Pin 1
VRef
I16 = 2 mA
V16 = 0 V
Pin 16-15
Pin 16
Pin 16
Pin 16
Pin 3
I3 = – 10 mA
I3 = – 10 mA
V13
vV vV
vV vV
4
6
vV
5
Max.
17
17.2
2
Unit
V
16.5
11.6
13.3
5.25
V
mA
14.8
10.4
11.7
4.75
11
12.5
5
Vlimit
– II
VTON
VTOFF
7.3
7.9
0.8
100
7.7
8.3
8.1
8.7
V
V
– II
V3
5
50
5.3
mA
4.7
9
37
10
40
1
450
600
11
43
mA
mA
– Ich1
– Ich2
Rdis
VTON
Vdis
V
V
mA
V
490
kW
mV
mV
I
VRef
500
V
nA
I
1
mA
VI
l
Pin 6
15
"I
"I
Pin 5
< 3.6 V
"
410
0
VI
V13
Typ.
Pin 2
Pin 2-1
Pin 4
V13
Min.
15
15.2
II
VTU
VTL
Rdis
1
VRef +1
VRef+0.3
+0 3
0
0.3
3.6
0.9
VS
4
1
1
500
4.4
1.1
V
nA
V
V
kW
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
U2102B
Parameters
Window discriminator
Input current
Upper threshold
Lower threshold
Input current window adjustment
Minimum window:
Lower threshold
Upper threshold
Maximum window:
Lower threshold
Upper threshold
Enable-Schmitt trigger
Input current
Enable threshold
Blocking threshold:
Output stage OFF
Output stage ON, except in the
case of two-stage reverse phase
control in second stage (a)
Threshold for test mode
Current monitoring
Input current
Switch-off threshold 1
Switch-off threshold 2
Switching output
Leakage current
Saturation voltage
Push-pull output stage
Upper saturation voltage,
ON state
Lower saturation voltage,
OFF state
Output current
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
Test Conditions / Pin
0V
vV vV
8
Pin 8
Pins 8 and 9
l
v vV
0 V V9
V9 = V13
1
V9 = V1
0V
0V
Symbol
Pin 9
Pin 8
"I
i
VTU
VTL
"I
Min.
0.55
0.45
Typ.
@V
@V
Ref + (0.2
Ref – (0.2
i
Max.
Unit
500
@V )
@V )
nA
9
9
V
500
nA
VTL1
VTU1
2.05
2.55
2.75
3.75
2.45
2.95
V
VTL2
VTU2
1.1
3.4
1.25
3.75
1.4
4.1
V
500
nA
VT
2.3
2.5
2.7
V
VT
1.8
0.45
2
0.5
2.2
0.55
V
VT
85
100
115
mV
80
450
100
500
500
120
550
nA
mV
mV
Ilkg
1
mA
VSat
VSat
1.0
1.2
V
V
– VSat
2.4
V
VSatL
1.2
V
Pin 8
Pin 7
vV vV
7
l
vV vV
11
Pin 11
1
"I
i
"I
i
VT1
VT2
Pin 12
V11 < 450 mV, V12
V11 > 550 mV
I12 = 0.5 mA
I12 = 10 mA
vV
15
I14 = – 10 mA
Pins 14 and 15
I14 = 10 mA
Pin 14
ON state
OFF state
Pin 14
–IO
IO
50
50
mA
11 (16)
U2102B
Applications
Vmains
230 V
X
94 8221
Load
GND
1 nF
Rsh
22 kW/2 W
R1
1 kW
IGBT
100 W
1N4007
Rsync
220 kW
RG
C1
47 mF/
25 V
100 kW
NTC
VRef
VS
16
15
14
13
12
11
10
9
6
7
8
U2102B
1
2
3
C3
10 nF
4
5
R3
820 kW
Control
100 kW
VS
GND
220 nF
22 kW
1 MW
R2
Enable
C2
CRef
Trigger
signal
1 mF
Figure 9. House number or staircase illumination for ac loads
House number illumination: V6 = V13
Staircase illumination: V6 = V15
12 (16)
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
U2102B
Vmains
230 V
X
94 8222
Load
GND
1 nF
Rsh
1 kW
IGBT
R1 = Rsync
18 kW/2 W
100 W
RG
68 kW
NTC
VRef
C1
47 mF/25 V
1N4007
VS
16
15
14
13
12
11
10
9
6
7
8
U2102B
1
2
3
C3
22 nF
4
5
R3
750 kW
C2
220 nF
Enable
22 kW
1 MW
Trigger
signal
R2
CRef
1 mF
Figure 10. Zero voltage switch mode for ac loads
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
13 (16)
U2102B
Vmains
230 V
X
94 8502
Load
1 nF
Rsh
R1
22 kW/2 W
1 kW
IGBT
100 W
VS
1N4007
Rsync
220 kW
RG
C1
47 mF/
25 V
100 kW
100 kW
VS
16
15
14
13
12
11
10
9
6
7
8
U2102B
1
2
4
3
5
C3
100 kW
10 nF
100 kW
R3
1 MW
VS
Control
100 kW
CRef
1 mF
Figure 11. Reverse phase control for ac loads
14 (16)
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
U2102B
Dimensions in mm
Package: DIP16
94 9128
Package: SO16
94 8875
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96
15 (16)
U2102B
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
16 (16)
TELEFUNKEN Semiconductors
Rev. A1, 30-May-96