LSI LS7541

LSI/CSI
UL
®
LS7541
LSI Computer Systems, Inc. 1235 Walt Whitman Road, Melville, NY 11747
(631) 271-0400 FAX (631) 271-0405
A3800
TOUCH CONTROL STEP DIMMER LIGHT SWITCH
WITH AUTOMATIC GAIN CONTROL (AGC)
FEATURES:
APPLICATIONS:
PIN ASSIGNMENT
TOP VIEW
CLOCK
1
SYNC
2
V DD (+V )
3
TOUCH
4
• Screw-in and built-in adapter modules for converting
table and floor lamps to touch control for step dimming.
• On-Off touch control of under-cabinet fluorescent lamps.
8
LS7541
Touch Sensitivity guaranteed to 600pF Touch Plate Capacitance.
Touch Operation independent of line plug polarity.
Pin selection of three available Brightness Step Sequences.
Minimal external components.
AGC Loop stabilizes immediately after Power-Up.
Brightness state is Off after AC power applied.
Brightness state is unchanged if AC power interrupted for < 0.5 sec.
Advanced CMOS design for reliable operating characteristics and low power.
50/60 Hz Line Frequency.
5V Operation (VDD - VSS).
LS7541 (DIP); LS7541-S (SOIC) - See Figure 1 -
LSI
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May 2006
TRIG
7
V SS (-V )
6
MODE
5
CONTROL
FIGURE 1
DESCRIPTION:
The LS7541 is a CMOS integrated circuit which provides trigger pulses for triac phase control of incandescent lamps.
The circuits are designed to operate with a wide variety of lamp sizes ranging from small table lamps to large floor lamps.
The AGC Loop automatically adjusts Touch Sensitivity to be independent of lamp size.
There are 3 different Brightness Step Sequences for each version of the IC which can be selected by the Three-State
MODE pin as shown in Table 1.
TABLE 1. BRIGHTNESS STEP MODES
MODE PIN
BRIGHTNESS STEP SEQUENCE
FLOAT
OFF-NIGHT LIGHT-MEDIUM-MAXIMUM-OFF
VDD
OFF-NIGHT LIGHT- LOW MEDIUM-HIGH MEDIUM-MAXIMUM-OFF
Vss
OFF-MAXIMUM-OFF
The lamp brightness is made to vary by changing the delay of the TRIG pulse to the triac from the zero-crossing of the
SYNC input. The delays are shown in Table 2 for 50Hz and 60Hz operation along with Delivered Power as a percentage
of Full Power. Figure 2 illustrates the delay.
TABLE 2. BRIGHTNESS POWER LEVELS
Brightness
Night Light
Low Medium
Medium
High Medium
Maximum
60Hz Delay (1)
6.0 ms
4.8 ms
4.0 ms
3.2 ms
0.85 ms
50Hz Delay (2)
7.2 ms
5.7 ms
4.8 ms
3.8 ms
1.0 ms
% PWR (3)
12
35
53
72
99
(2) With 470kΩ connected between Pin 1 and VDD.
(1) With 400kΩ connected between Pin 1 and VDD.
(3) Percentage of Full Power delivered to a resistive load by the Triac Switch.
7541-051106-1
FIGURE 2. OUTPUT DELAY (Td)
SYNC (Pin 2)
TRIG(Pin 8)
Td
Td
INPUT/OUTPUT DESCRIPTION:
CLOCK Input (Pin 1)
An external resistor connected between this input and
VDD, along with an internal capacitor and oscillator stage,
generates a clock which is used for all timing functions.
The recommended value of this resistor for 50Hz and
60Hz operation is specified in the ELECTRICAL CHARACTERISTICS. The resistor value determines the Brightness Levels produced. (See Table 2)
CONTROL I/O (Pin 5)
An external R-C network connected between this pin
and VDD establishes the controlling feedback for the
AGC Loop.
SYNC Input (Pin 2)
50 or 60Hz AC input for zero crossing detection.
VSS (Pin 7)
Supply voltage negative terminal.
VDD (Pin 3)
Supply voltage positive terminal.
TRIG (Pin 8)
The TRIG output produces a negative going pulse every half-cycle of the SYNC input to trigger the triac. The
delay, Td, of the pulse with respect to the SYNC signal
determines the Brightness Level produced.
(See Table 2 & Figure 2)
TOUCH Input (Pin 4)
Input for sensing that a touch has been made
on a lamp surface or other touch plate.
MODE Input (Pin 6)
A three-state input used to select the desired
Brightness Step Sequence (See Table 1).
ABSOLUTE MAXIMUM RATINGS:
PARAMETER
SYMBOL
VALUE
UNIT
DC supply voltage
Any input voltage
Operating temperature
Storage temperature
VDD - VSS
VIN
TA
TSTG
+7
VSS - 0.5 to VDD + 0.5
-20 to +85
-65 to +150
V
V
°C
°C
The information included herein is believed to be
accurate and reliable. However, LSI Computer Systems,
Inc. assumes no responsibilities for inaccuracies, nor for
any infringements of patent rights of others which may
result from its use.
7541-072805-2
ELECTRICAL CHARACTERISTICS:
( All voltages referenced to Vss. TA = +25˚C unless otherwise specified.)
PARAMETER
Supply Voltage
Supply Current
SYMBOL
VDD
IDD
MIN
+4.5
-
TYP
-
MAX
+5.5
1.0
UNIT
V
mA
TRIG Sink Current
Vo = VDD - 3V
IO
-50
-
-
mA
VDD = +5.0V
TRIG Source Current
Vo = VDD - 0.2V
IO
+0.1
-
-
mA
VDD = +5.0V
TRIG Pulse Width
TW
-
-
100
115
-
µs
µs
RC = 400kΩ, 60Hz
RC = 470kΩ, 50Hz
TRIG Pulse Delay
(Medium Brightness)
Td
-
4.0
4.8
-
ms
ms
Rc = 400kΩ, 60Hz
Rc = 470kΩ, 50Hz
CLOCK Resistor
RC
-
-
400
470
-
kΩ
kΩ
60Hz
50Hz
-
-
10
1
-
MΩ
µF
-
CL
-
-
600
pF
-
CONTROL Resistor
Capacitor
Touch Plate Capacitance
MODE
6
SYNC
2
ZERO-CROSS
DETECTOR
CLOCK
1
OSCILLATOR
TOUCH
4
AGC CIRCUIT
COUNTER
DECODER
STEPPER
5
CONTROL
7541-072805-3
CONDITIONS
Output off,
VDD = +5.0V
V DD
3
+V
V SS
7
-V
FIGURE 3
LS7541 BLOCK DIAGRAM
OUTPUT
DRIVER
8 TRIG
FIGURE 4. TOUCH LAMP APPLICATION SCHEMATIC
+V
R1
LOAD
D1
MT2
+
C1
AC
MAINS
-
Z1
T1
R5
MT1
+
C6
G
-
R6
-V
SEE
NOTE 1
C5
C2
8
7
TRIG
V SS
6
5
MODE
CONT
C7* (SEE NOTE 2)
LS7541
CLOCK SYNC V DD
2
1
R2
TOUCH
4
3
D2
R4
D3
R3
TOUCH PLATE
(LAMP BODY)
C3
115VAC APPLICATION
R1 = 20kΩ, 1W
C4 = 1000pF, 1kV
R2 = 470kΩ, 1/4W
C5 = 0.03µF, 10V
R3 = 1kΩ, 1/4W
C6 = 1µF, 10V
(1) R4 = 400kΩ, 1/4W, 1%
Z1 = 5.1V, 1/4W Zener
R5 = 10MΩ, 1/4W
D1 = 1N4004
R6 = 100Ω, 1/4W
D2 = 1N4148
C1 = 47µF, 10V
D3 = 1N4148
C2 = 1000pF, 10V
T1 = Q2004L4 (Typical Triac)
C3 = 1000pF, 1kV
or Q2004F41 (Typical Triac)
C4
220VAC APPLICATION
R1 = 39kΩ, 2W
R2 = 910kΩ, 1/4W
(1) R4 = 470kΩ, 1/4W, 1%
D1 = 1N4005
T1 = Q4004L4 (Typical Triac)
or Q4004F41 (Typical Triac)
All other values remain the same.
(1) Resistor should be placed adjacent to Pin 1.
NOTE 1: Connect MODE (Pin 6) for desired Brightness Step Sequence (See Table 1).
NOTE 2: A good PCB layout using through-hole components will provide protection for ESD introduced at the Touch Plate in the range
of 25kV. Using surface mount components and/or a poor PCB layout can reduce the ESD protection. The OEM can increase
the ESD protection provided by the product with any combination of the following steps:
Step 1: The most effective and least costly way to increase ESD protection is to create a spark gap around the Touch Plate input on
the PCB. This will increase ESD protection on a good PCB layout to abut 35kV. The gap should be made with a split metal ring
with each side of the metal ring connected back to opposite sides of the AC line. This ensures that a path for the spark back to
house ground through AC Neutral exists independent of line plug polarity. The split ring and the center conduction plate should
be constructed so that the spacing between them conforms to UL requirements. The spark gap will absorb most of the ESD
leaving a remnant of about 10kV for the rest of the circuit to absorb.
Step 2: Increase R3 from 1kΩ to 5.1kΩ and add C7, a 0.1µF capacitor, between VDD and Vss.
(A minimal loss in touch sensitivity may be experienced.)
Step 3: Replace diodes D2 and D3 (1N4148) with Schottky diodes (1N5819 or similar)
7541-011706-4
FIGURE 5. TOUCH LAMP APPLICATION SCHEMATIC
-V
LOAD
R1
D1
C1
AC
MAINS
Z1
+
MT2
T1
G
MT1
SEE
NOTE1
R6
+
+V
C6
R5
7
8
C2
TRIG
6
V SS MODE
-
5
CONT
C7*
LS7541
(SEE NOTE 2)
CLOCK SYNC V DD TOUCH
R2
1
2
3
4
D2
R4
D3
TOUCH PLATE
(LAMP BODY)
C3
C4
R3
The Figure 5 Application Schematic functions identically to that shown in Figure 4 with one less component.
Referencing Triac T1 to the +V power supply of the IC eliminates the need to AC couple the TRIAC pulse
to the Triac Gate thereby eliminating component C5.
7541-051106-5