ETC 1DDD372AA-M04

Load A*
Sample Output Waveform
100Ω
10 nF
* Load A approximates a 3in2 EL lamp.
Absolute Maximum Ratings:
Parameter
Supply voltage
Operating range
Withstand range
Enable Voltage
Lamp Output
Operating temperature
Storage temperature
Symbol
Minimum
V+
2.0
-0.5
-0.5
E
Vout
Ta
Ts
Maximum
6.5
9.0
(V+) +0.5
220
85
150
-40
-65
Unit
V
V
Vpp
°C
°C
Comments
E = V+
E = GND
E = V+
Note: The above are stress ratings only. Functional operation of the device at these ratings or any other above
those indicated in the specifications is not implied. Exposure to absolute maximum rating conditions for extended
periods of time may affect reliability.
Physical Data:
PIN # NAME
1
10
2
9
3
8
4
7
5
6
1
2
3
4
5
6
7
8
9
10
2
V+
CLF
CHF
E
GND
L+
Cs
EL1
EL2
Rd
FUNCTION
DC power supply input
Low frequency oscillator capacitor/LF clock input
High frequency oscillator capacitor/HF clock input
System enable: HI = On
System ground connection
Charge pumping inductor input
High voltage storage capacitor
AC output to lamp
AC output to lamp
Wave shaping resistor
400
400
350
350
300
300
LF (Hz)
LF (Hz)
Typical Performance Characteristics Using Standard Test Circuit
250
200
250
200
150
150
100
100
50
50
0
0
1
2
3
4
5
6
-40
7
-20
40
60
80
Temperature ( C)
DC Input Voltage
Output Frequency vs. Ambient Temperature
300
300
250
250
Ouput Voltage (Vpp)
Output Voltage (Vpp)
20
o
Output Frequency vs. DC Supply Voltage
200
150
100
50
0
200
150
100
50
0
1
2
3
4
5
6
7
-40
-20
0
20
40
60
DC Input Voltage
Temperature ( oC)
Output Frequency vs. DC Supply Voltage
Output Frequency vs. Ambient Temperature
80
25
Avg Supply Current (mA)
25
Avg Supply Current (mA)
0
20
15
10
5
20
15
10
5
0
0
1
2
3
4
5
6
-40
7
-20
0
20
40
60
o
Temperature ( C)
DC Input Voltage
Output Frequency vs. Ambient Temperature
Output Frequency vs. DC Supply Voltage
3
80
Block Diagram of the Driver Circuitry
VBAT
E
V+
L+
CS
CHF
CLF
L
o
g
i
c
High
Frequency
Oscillator
Low
Frequency
Oscillator
L
o
g
i
c
Divide
by 2
Rd
GND
EL1
EL2
EL Lamp
Theory of Operation
Electroluminescent (EL) lamps are essentially capacitors with one transparent electrode and a special phosphor material
in the dielectric. When a strong AC voltage is applied across the EL lamp electrodes, the phosphor glows. The
required AC voltage is typically not present in most systems and must be generated from a low voltage DC source.
The D372 chip inverter drives the EL lamp by using a switching BJT to repeatedly charge an external inductor and
discharge it to the high voltage capacitor Cs. The discharging causes the voltage at Cs to continually increase. When
the voltage at Cs reaches a nominal value, the switching BJT is turned off. The internal circuitry uses the H-bridge
technology, using both electrodes to drive the EL lamp. One of the outputs, EL1 or EL2, is used to discharge Cs into the
EL lamp during the first half of the low frequency (LF) cycle. By alternating the state of the H-bridge, the other output
is used to charge the EL lamp during the second half of the LF cycle. The alternating states make it possible to achieve
200V peak-to-peak across the EL lamp.
The EL driving system is divided into several parts: on-chip logic control, on-chip high voltage output circuitry, on-chip
discharge logic circuitry, and off-chip components. The on-chip logic controls the lamp operating frequency (LF) and
the inductor switching frequency (HF). These signals are used to drive the high voltage output circuitry (H-bridge) by
delivering the power from the inductor to the lamp. The integrated discharge logic circuitry uses a patented wave
shaping technique for reducing audible noise from an EL lamp. Changing the Rd value changes the slope of the linear
discharge as well as the shape of the waveform. The off-chip component selection provides a degree of flexibility to
accommodate various lamp sizes, system voltages, and brightness levels.
Typical D372 EL driving configurations for driving EL lamps in various applications are shown on the following page.
The expected system outputs for the various circuit configurations are also shown with each respective figure. These
’ Kit, which includes a printed
examples are only guides for configuring the driver. Durel provides a D372 Designers
circuit evaluation board intended to aid you in developing an EL lamp driver configuration using the D372 that meets
your requirements. A section on designing with the D372 is included in this datasheet to serve as a guide to help you
select the appropriate external components to complete your D372 EL driver system.
4
Typical D372A EL Driver Configurations
1.0 kΩ
3.0V Handset LCD
+3.0 V
2.0 nF
0.1 µF
Typical Output
Brightness = 6.0 fL (20.6 cd/m2)
Lamp Frequency = 285 Hz
Supply Current = 12 mA
Vout = 208 Vpp
Load = 1 in2 (645 mm2) Durel® 3
Green EL
3.0 V
0V
on
68 pF
off
1 V+
Rd 10
2 CLF
EL2 9
3 CHF
EL1 8
47 nF
Cs 7
4 E
5 GND
D372A
L+ 6
Bujeon
BDS-3516S
1.5 mH
+3.0 V
1.0 in 2
EL Lamp
3.3 V Handset LCD and Keypad
1.0 kΩ
+3.3 V
Typical Output
2.0 nF
Luminance = 5.5 fL (18.8 cd/m2)
Lamp Frequency = 290 Hz
Supply Current = 17 mA
Vout = 200 Vpp
Load = 1.5 in2 (950 mm2)Durel® 3
Green EL
0.1 µF
3.3 V
on
68 pF
0 V off
Rd 10
1 V+
2 CLF
EL2 9
3 CHF
EL1 8
47 nF
Cs 7
4 E
L+ 6
5 GND
D372A
Murata
LQH3KS
2.2 mH
+3.3 V
1.5 in2
EL Lamp
220 Ω
5.0 V LCD Backlight
+5.0 V
Typical Output
0.1 µF
2.0 nF
Luminance = 6.0 fL (24.3 cd/m )
Lamp Frequency = 300 Hz
Supply Current = 22 mA
Vout = 206 Vpp
Load = 4 in2 (2580 mm2)Durel® 3
Green EL
1 V+
Rd 10
2 CLF
EL2 9
3 CHF
EL1 8
2
5.0 V on
68 pF
0 V off
47 nF
4 E
Cs 7
5 GND
L+ 6
D372A
4.0 in2
EL Lamp
5
Sumida
CLS62
1.5 mH
+5.0 V
Designing With D372
I. Lamp Frequency Capacitor (CLF) Selection
Selecting the appropriate value of capacitor (CLF) for the low frequency oscillator will set the output frequency of the
D372 inverter. Figure 1 graphically represents the effect of the CLF capacitor value on the oscillator frequency at
V+ = 3.0V.
Lamp Frequency (Hz)
600
500
400
300
200
100
1
2
3
4
5
CLF (nF)
Figure 1: Typical Lamp Frequency vs. CLF Capacitor
The lamp frequency may also be controlled with an external clock signal. The resulting lamp frequency will be half of
the clock signal frequency. The differential output voltage will increase in magnitude during the high portion of the
clock signal and decrease during the low portion of the clock signal. Lamp frequencies of 200-500Hz are typically
used.
The selection of the CLF value can also affect the output brightness and current consumption of the driver. The EL
lamp frequency (LF) depends on lamp size, drive conditions, and mainly on the CLF value selected. Figures 2 and 3
show typical brightness and current draw of a D372 circuit at different frequencies. The data was taken with an
average 1.0mH inductor and 68 pf CHF capacitor.
45
Luminance
8
9
8
40
Current
7
4
25
3
Luminance (fL)
30
35
6
Current (mA)
Luminance (fL)
35
5
40
Current
7
6
45
Luminance
20
5
30
4
25
3
20
2
2
15
1
0
0
100
200
300
400
500
15
1
10
600
0
0
Frequency (Hz)
100
200
300
400
500
Frequency (Hz)
Figure 2: Typical Luminance and Current
vs. Lamp Frequency
Conditions: V+ = 3.0 V, 1.5 in2 EL Lamp
Figure 3: Typical Luminance and Current
vs. Lamp Frequency
Conditions: V+ = 5.0 V, 4.0 in2 EL Lamp
6
10
600
Current (mA)
9
II. Inductor Switching Frequency (CHF) Selection
Selecting the appropriate value of capacitor (CHF) for the high frequency oscillator will set the inductor switching
frequency of the D372 inverter. Figure 4 graphically represents the effect of the CHF capacitor value on the oscillator
frequency at V+ = 3.0V.
Inductor Frequency (KHz)
25
20
15
10
50
75
100
125
150
175
200
CHF (pF)
Figure 4: Typical Inductor Frequency vs. CHF Capacitor
The inductor switching frequency may also be controlled with an external clock signal. The inductor will charge
during the low portion of the clock signal and discharge into the EL lamp during the high portion of the clock signal.
III. Inductor (L) Selection
The inductor value and inductor switching frequency have the greatest impact on the output brightness and current
consumption of the driver. Figures 5 and 6 show typical brightness and current draw of a D372 circuit with several
different inductor and CHF values. The CLF value was modified in each case such that the output voltage was
approximately 200Vpp. The data was taken with average inductors. Please note that the DC resistance (DCR) and
current rating of inductors with the same inductance value may vary with manufacturer and inductor type. Thus,
inductors made by a different manufacturer may yield different outputs, but the trend of the different curves should be
similar.
Luminance (fL)
7
6
9
45
8
40
7
35
5
30
4
25
3
1
0
0.0
1.0
2.0
3.0
4.0
5.0
68 pF Luminance
100 pF Luminance
68 pF Current
100 pF Current
45
40
6
35
5
30
4
25
3
20
2
50
20
2
15
1
10
0
6.0
15
10
0.0
1.0
2.0
3.0
4.0
5.0
CLF (nF)
CLF (nF)
Figure 5: Luminance and Current
vs. Inductor and CHF Value
Conditions: V+ = 3.0 V, 1.5 in2 EL Lamp
Figure 6: Luminance and Current
vs. Inductor and CHF value
Conditions: V+ = 5.0 V, 4in2 EL Lamp
7
6.0
Current (mA)
8
50
Luminance (fL)
68 pF Luminance
100 pF Luminance
68 pF Current
100 pF Current
Current (mA)
9
IV. Wave-Shape (Rd) Selection
The Rd resistor determines the slope of the charge and discharge portions of the output waveform. The optimal value
of this resistor depends on the lamp size and drive conditions. Typical values range from 0Ω - 2.0kΩ. Recommended
starting values for various lamp sizes are shown in the table below. The optimal waveform is trapezoidal which will
result in the best combination of high brightness and low audible noise performance. Using a larger value of Rd than
recommended will result in a triangular waveform and correspond to reducing the audible noise of the EL lamp and
increase lamp life. However, the luminance of the EL lamp will decrease. Using a smaller value of Rd than recommended will result in a square waveform and correspond to higher initial luminance from the EL lamp, but will not take
advantage of the noise reduction capability of the D372.
Rd
Lamp Size
1.2kΩ
820Ω
470Ω
220Ω
<1.0 in2
1.0-2.0 in2
2.0-4.0 in2
>4.0 in2
Typical waveforms corresponding to the selected Rd values for a 2in2 lamp and a 4in2 lamp are shown below.
Lamp Size 2 in2
Rd = 820 Ω
2
Optimal waveform for 2 in
Rd = 1.2k Ω
Reduced noise with lower luminance
Lamp Size 4 in2
Rd = 470 Ω
2
Optimal waveform for 4 in
Rd = 0 Ω
Higher luminance with more noise
8
V. Storage Capacitor (Cs) Selection
The Cs capacitor is used to store the energy transferred from the inductor. Capacitors with larger values have a larger
time constant and will store the energy for longer periods of time. The recommended Cs values range from 10nF to
47nF and are to be rated to at least 100V. Larger EL lamps typically require larger values of Cs. In general, increasing
the value of Cs will increase the RMS voltage and increase the brightness of an EL lamp. Typical waveforms for
varying Cs values for a 2.0 in2 lamp are shown below.
Cs = 10nF
Cs = 22nF
Cs = 47nF
9
D372 Design Ideas
I. Lamp Frequency Control With an External Clock Signal
An external clock signal may be used to control the EL lamp frequency (LF) by applying the clock signal to the CLF pin.
The oscillator frequency can be varied to synchronize the inverter with other elements in the application. An internal
divider network in the IC divides the clock signal by two. The recommended clocking frequencies range from 500Hz
to 1kHz and result in an EL lamp frequency range of 250Hz to 500Hz respectively. The amplitude of the clock signal
typically ranges from 1.0V to V+.
Vbat
LF CLK
50%DC
1V
0.1µ F
1 V+
Rd 10
2 CLF
EL2 9
3 CHF
EL1 8
Rd
0V
EL Lamp
CHF
on
off
Cs
4 E
Cs 7
5 GND
L+ 6
D372A
Vbat
L
II. Controlling EL Brightness Through Clock Pulse Width Modulation
An external clock signal may be used to control the inductor oscillating frequency (HF). Pulse width modulation of the
external clock signal may be used to regulate the brightness of an EL lamp. In this circuit, when the positive duty cycle
of the external clock is at 20%, the lamp is at full brightness. Incremental dimming occurs as the positive duty cycle is
increased to as high as 85%. This scheme may also be used inversely to regulate lamp brightness over the life of the
battery or to compensate for lamp aging. (Note: Operation at duty cycles higher than 85% and lower than 20% is not
recommended.) The recommended clocking frequency ranges from 10kHz to 24kHz, and the amplitude of the clock
signal typically ranges from 1.0V to V+.
Rd
Vbat
CLF
0.1µF
1V
on
off
0V
HF CLK
20%-85% +DC
1 V+
Rd 10
2 CLF
EL2 9
3 CHF
EL1 8
EL Lamp
Cs
4 E
Cs 7
5 GND
L+ 6
D372A
10
Vbat
L
III. Split Voltage Supply
A split supply voltage may also be used to drive the D372. To operate the on-chip logic, a regulated voltage supply (V+)
ranging from 2.0V to 6.5V is applied. To supply the D372 with the necessary power to drive an EL lamp, another supply
voltage (Vbat) is applied to the inductor. The voltage range of Vbat is determined by the following conditions: driver
application, lamp size, inductor selection, and voltage and current limitations.
Two different examples of the split supply are shown below. The first example shows a regulated 3.0V applied to the
V+ pin, and a Vbat voltage that may range from 2.7V to 4.5V. The enable voltage is in the range of 2.0V to 3.0V. This
is a typical setup used in cell phone applications.
V+
Regulated 3.0 V
CLF
0.1µF
Rd 10
1 V+
2 CLF
EL2 9
3 CHF
EL1 8
Rd
EL Lamp
2.0V - 3.0V on
CHF
0 V off
Cs
4 E
Cs 7
5 GND
L+ 6
D372A
Vbat
2.7 V - 4.5 V
L
The second example shows that V+ may range from 2.0V to 6.5V, and the Vbat voltage may be as high as 12.0V.
The enable voltage is in the range of 2.0V to V+. This is useful in many high voltage applications.
V+
2.0 V - 6.5 V
CLF
0.1 µF
1 V+
Rd 10
2 CLF
EL2 9
3 CHF
EL1 8
Rd
EL Lamp
2.0V - V+ on
0V off
CHF
Cs
Cs 7
4 E
L+ 6
5 GND
D372A
11
L
Vbat
12.0 V
Ordering Information
The D372A IC is available in standard MSOP-10 plastic package per tape and reel. A Durel D372 Designer’s Kit
(1DDD372AA-K01) provides a vehicle for evaluating and identifying the optimum component values for any particular
application using D372. Durel engineers also provide full support to customers including specialized circuit optimization and application retrofits.
MSOP-10
Min.
F
mm.
I
H
D
E
C
A
G
B
A
B
C
D
E
F
G
H
I
0.92
0.05
0.15
0.40
0.13
2.90
0.35
4.75
2.90
Typical
Max.
in.
mm.
in.
0.036
0.002
0.006
0.016
0.005
0.114
0.014
0.187
0.114
1.00
0.10
0.23
0.55
0.18
3.00
0.50
4.90
3.00
0.039
0.004
0.009
0.022
0.007
0.118
0.020
0.193
0.118
mm.
1.08
0.15
0.31
0.70
0.23
3.10
0.65
5.05
3.10
in.
0.043
0.006
0.012
0.028
0.009
0.122
0.026
0.199
0.122
MSOPs are marked with part number (372A) and 3-digit wafer lot
code. Bottom of marking is on the Pin 1 side.
RECOMMENDED PAD LAYOUT
b
MSOP-10 PAD LAYOUT
a
Min.
mm.
c
d
f
e
a
b
c
d
e
f
3.3
0.89
5.26
Typical
in.
0.130
0.035
0.207
Max.
mm.
in.
0.5
2.0
0.0197
0.0788
0.97
0.038
0.3
0.012
mm.
3.45
1.05
5.41
in.
0.136
0.041
0.213
MSOPs in Tape and Reel:
1DDD372AA-M04
Embossed tape on 360 mm diameter reel per EIA-481-2.
2500 units per reel. Quantity marked on reel label.
Tape Orientation
ISO 9001 Certified
DUREL Corporation
2225 W. Chandler Blvd.
Chandler, AZ 85224-6155
Tel: (480) 917-6000
FAX: (480) 917-6049
Website: http://www.durel.com
The DUREL name and logo are registered trademarks of DUREL CORPORATION.
This information is not intended to and does not create any warranties, express or implied, including any warranty of merchantability or fitness for a
particular purpose. The relative merits of materials for a specific application should be determined by your evaluation.
This driver is covered by the following U.S. patents: #5,313,141, #5,789,870; #6,297,597 B1. Corresponding foreign patents are issued and pending.
© 2000, 2001 Durel Corporation
Printed in U.S.A.
12
LIT-I9032 Rev. A04
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