ETC 1DDD371AA-M03

Data Sheet
D371A
Electroluminescent
Lamp Driver IC
General Description:
The Durel® D371A Lamp Driver is part of a family of
switch-mode IC drivers intended to reduce EL system
cost, improve performance and to simplify the design,
specification, and manufacture of EL backlighting
systems. This driver is optimized for cellular phone and
databank backlighting applications.
MSOP-10
Features
•
•
•
•
•
•
A
pplications
Applications
Flexible Wave shaping Capability
High Efficiency
Small Package Size
Adjustable Output Frequency
High AC Voltage Output
External Clock Compatible
•
•
•
Cellular / PHS Phones
Data Banks
LCD Backlighting
Lamp D
er SSpecifications:
pecifications:
Drriv
iver
(V+=3.0V, CLF=3.9nF, CHF=68pF, L=2.2mH/4Ω, E=V+, Renable=0Ω, DCH open, Load 2*, Ta=25°C,
unless otherwise specified)
Parameter
Symbol
Supply Current
Standby Current
Enable Current
Enable Voltage
On
Off
Inductor Frequency
Lamp Frequency
Output Voltage
Minimum
Typical
I
15
5
15
E
2.6
HF
LF
VOUT
190
160
23
260
188
Maximum
18
1000
0.4
330
215
Typical Wav
efor
m
avefor
eform
* Load 2
100Ω
10 nF
1
Unit
Conditions
mA
nA
µA
E = GND
E = 3.0V
V
V
kHz
Hz
Vpp
CHF=68pF
CLF=3.9nF
Absolute Maximum Ratings:
Parameter
Symbol
Supply voltage
Operating range
Withstand range
Output Voltage
Enable voltage
Operating temperature
Storage temperature
Solder temperature
CHF (Pin 1) Voltage
CLF (Pin 2) Voltage
Minimum
Maximum
Unit
Comments
V
V+
2.0
-0.5
Vout
E
Ta
Ts
6.5
9.0
220
(V+) +0.5
85
150
300
(V+)+0.3V
(V+)+0.3V
-0.5
-40
-65
245
GND
GND
VCHF
VCLF
Vpp
V
°C
°C
°C
V
V
Peak to peak voltage
5 second soak
Note: The absolute maximum ratings are stress ratings only. Functional operation of the device at these ratings or any other conditions above those
indicated in the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect life of lamp or driver.
Physical D
ata:
Data:
Pad C
enter Locations
Center
Xµm Yµm
Name
N
ame
CHF
CLF
E
DCH
GND
N/C
LV-out
L+
V+
-427
-427
-426
-445
-459
467
473
473
475
728
463
-413
-583
-776
-345
-78
190
786
MSOP
Pin-outs
1
2
3
4
5
6
7
8
9
10
Function
V+
CHF
Capacitor input to high frequency oscillator
Capacitor input to low frequency oscillator
System Enable
Wave shaping input
Power ground
Not connected
Negative power connection to inductor
Output voltage to EL lamp
Positive power connection to inductor
System power input
CLF
L+
0
VOUT
0
L-
E
DCH
GND
Notes:
1. Dimensions are in microns, unless otherwise noted.
2. Bond pads are typically 100 x 100.
3. Die thickness is 330 +/- 25 (13 +/- 1 mil).
4. Pad center coordinates are relative to origin on center of die.
5. Die size is 1170 x 1760.
6. Base of die should be grounded.
Block D
iagram of the IInv
nv
er
ter C
ir
cuitr
y:
Diagram
nver
erter
Cir
ircuitr
cuitry:
1.0µF
Renable
V BAT
DCH
E
V+
L+
CLF
Low
Frequency
Oscillator
Constant
current
discharge
Discharge
logic
CHF
High
Frequency
Oscillator
L-
VOUT
EL Lamp
2
GND
Typical D371A EL D
er Configuration:
Drriv
iver
3.0V Cellular LCD
Typical O
utput
Output
Brightness = 6.75 fL (23.1 Cd/m2)
Lamp Frequency = 460 Hz
Supply Current = 16mA
Vpp = 190
Load = 1.5in2
3.3 V C
ellular Display and K
Cellular
Keeypad
Typical O
utput
Output
Brightness = 4.45 fL (15.2 Cd/m2)
Lamp Frequency = 275 Hz
Supply Current = 12mA
Vpp = 185
Load = 2.25in2
5.0 V PDA
Typical O
utput
Output
Brightness = 5.5fL (18.8 Cd/m2)
Lamp Frequency = 285 Hz
Supply Current = 15mA
Vpp = 200
Load = 4in2
3
DESIGNING WITH D371
The Durel® D371A Lamp Driver is part of a family of switch-mode IC drivers intended to reduce EL system cost,
improve performance and to simplify the design, specification, and manufacture of EL backlighting systems. This
driver is optimized for cellular phone and databank backlighting applications.
A typical D371 circuit is represented in Figure 1. This application guideline is furnished to help you optimize your
EL driver circuit design. It provides typical system outputs, such as lamp luminance and supply current draw, for
various circuit configurations. Durel also provides a Designer’s Kit, which includes a printed circuit board to aid you
in developing an EL lamp driver configuration that meets your requirements.
Figur
ir
cuit D
esign
iguree 1: Typical D371 C
Cir
ircuit
Design
I. Lamp Frequency
Selecting the appropriate value of capacitor (CLF) for the low frequency oscillator will set the output
frequency of the D371 inverter. Figure 2 graphically represents the effect of the CLF capacitor value
on the oscillator frequency at V+ = 3.0V.
900
Lamp Frequency (Hz)
800
700
600
500
400
300
200
100
0
1
2
3
4
5
6
7
8
9
10
CLF (nF)
Figur
equency vs. CLF capacitor
iguree 2: Typical Lamp fr
frequency
4
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 output voltage (pin 8) will increase in magnitude during the low portion of the clock signal and linearly decrease during the high portion of the
clock signal.
Lamp frequencies of 200-500Hz are typically used. The lamp frequency should always be set so that
the output voltage does not exceed 200Vpp.
II. Inductor Switching Frequency
Selecting the appropriate value of capacitor (CHF) for the high frequency oscillator will set the inductor switching frequency of the D371 inverter. Figure 2 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
225
CHF (pF)
Figur
equency vs. CHF capacitor
iguree 3: Typical inductor fr
frequency
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 Selection
The inductor value and inductor switching frequency have the greatest impact on the output brightness and current consumption of the driver. Figures 4 and 5 show typical brightness and current
draw of a D371 circuit with several different inductor and CHF values. The CLF value was modified in each case such that the output voltage was approximately 190Vpp. 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.
5
50.0
9.00
45.0
8.00
40.0
7.00
35.0
6.00
30.0
5.00
25.0
4.00
20.0
3.00
Current (mA)
Brightness (Ft-L)
10.00
15.0
68 pF Brightness
100 pF Brightness
2.00
10.0
68 pF Current
100 pF Current
1.00
5.0
0.00
0.0
0.39
0.47
0.56
0.68
0.82
1.00
1.20
1.50
1.80
2.20
2.70
3.30
3.90
Inductor (mH)
Figure 4: Brightness and current vs. inductor and CHF value.
Conditions: V+=3.0V, Lamp=2.0in2
12.00
70.0
60.0
10.00
50.0
40.0
6.00
30.0
4.00
20.0
68 pF Brightness
100 pF Brightness
2.00
68 pF Current
10.0
100 pF Current
0.00
0.0
0.39
0.47
0.56
0.68
0.82
1.00
1.20
1.50
1.80
2.20
2.70
3.30
Inductor (mH)
Figure 5: Brightness and current vs. inductor and CHF value.
Conditions: V+=5.0V, Lamp=4.0in2
6
3.90
Current (mA)
Brightness (Ft-L)
8.00
IV. Wave-Shaping
The D371 inverter uses a patented wave-shaping technique for reducing audible noise from an EL lamp. The
linear discharge of the output waveform may be adjusted by selecting one of 4 lamp discharge levels. The optimal
discharge level for an application depends on the lamp size, lamp brightness, etc. To ensure that the D371 is
configured optimally, each level should be evaluated. In many cases, the lower discharge levels result in lower
audible noise from the EL lamp.
Discharge level
Renable
DCH pin
Typical Lamp SSiz
iz
izee
1 (slowest)
2
3
4 (fastest)
80kΩ
0Ω
80kΩ
0Ω
Open
Open
GND
GND
0.5-1.5 in2
1.0-2.5 in2
1.5-3.5 in2
>3.5 in2
V. Output Voltage
The inductor and CLF capacitor should be set such that the output voltage of the D371A inverter does not exceed
200Vpp. In some cases, a pair of zener diodes connected to the output (as shown below) is recommended to
prevent over-voltage on pin 8. Durel can provide assistance in optimizing circuit components for your application.
7
Ordering Information:
The D371A inverter is available as bare die in probed wafer form or in die trays, and in a standard MSOP-10 plastic
package per tube or per tape and reel. A Durel D371A Designer’s Kit is available for evaluating and identifying the
optimum component values for your application.
MSOP-10
Min.
Description
A
B
C
D
E
F
G
H
J
mm.
0.92
0.05
0.15
0.40
0.13
2.90
0.35
4.75
2.90
F
Typical
in.
0.036
0.002
0.006
0.016
0.005
0.114
0.014
0.187
0.114
mm.
1.00
0.10
0.23
0.55
0.18
3.00
0.50
4.90
3.00
Max.
in.
mm.
in.
0.039
0.004
0.009
0.022
0.007
0.118
0.020
0.193
0.118
1.08
0.15
0.31
0.70
0.23
3.10
0.65
5.05
3.10
0.043
0.006
0.012
0.028
0.009
0.122
0.026
0.199
0.122
I
D
E
C
A
G
MSOPs are marked with direct logo part number (371A) and
wafer lot number. Marking orientation is bottom closest to pin
1 side.
H
B
MSOPs in Tubes: 1DDD371AA-M03
MSOPs in Tape & Reel: 1DDD371AA-M04
Tube-length = 320 mm (12.6 in). 100 units per
tube.
Embossed tape on 360 mm diameter reel per EIA-481-2.
2500 units per reel. Quantity marked on reel label.
Die in Trays: 1DDD371AA-B02
!
!
!
!
Tape Orientation
Die tray size is 2 inches square
Total number of pockets is 100
Pocket depth is 890µm (0.035”)
Pocket area is 2030µm x 2030µm (0.080” x 0.080”)
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 inverter is covered by the following U.S. patents: #5,313,141, #5,789,870. Corresponding foreign patents are issued and pending.
© 2000, Durel Corporation
Printed in U.S.A.
LIT-I 9028 Rev. A07