® SP4425 Electroluminescent Lamp Driver Low Voltage Applications ■ Low Voltage, Single Battery Operation (VBATTERY > 1.1 VDC) ■ DC to AC Inverter for EL Backlit Display Panels ■ Externally Adjustable Internal Oscillator ■ Low Current Standby Mode APPLICATIONS ■ Pagers ■ Digital Watches ■ Backlit LCD Displays DESCRIPTION The SP4425 is a high voltage output DC-AC converter that can operate from a single 1.5 VDC power supply. The SP4425 is capable of supplying up to 220 VPP signals, making it ideal for driving electroluminescent lamps. The device features 1 µA (typical) standby current for use in low power portable products. One external inductor is required to generate the high voltage charge and one external capacitor is used to select the oscillator and lamp frequencies. The SP4425 is offered in both an 8-pin narrow SOIC and 8-pin micro SOIC package. For delivery in die form, please consult the factory. 8 HON 7 VDD 3 6 EL1 4 5 EL2 COSC 1 VSS 2 COIL D1 SP4425 SP4425 Block Diagram SP4425DS/20 SP4425 Electroluminescent Lamp Driver 1 © Copyright 2000 Sipex Corporation ABSOLUTE MAXIMUM RATINGS The information furnished herein by Sipex has been carefully reviewed for accuracy and reliability. Its application or use, however, is solely the responsibility of the user. No responsibility for the use of this information is assumed by Sipex, and this information shall not explicitly or implicitly become part of the terms and conditions of any subsequent sales agreement with Sipex. Specifications are subject to change without prior notice. By the sale or transfer of this information, Sipex assumes no responsibility for any infringement of patents or other rights of third parties which may result from its use. No license or other proprietary rights are granted by implication or otherwise under any patent or patent rights of Sipex Corporation. These are stress ratings only and functional operation of the device at these ratings or any other above those indicated in the operation sections of the specifications below is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect reliability. VDD...................................................................................................................5V Input Voltages/Currents HON (pin1)........................................-0.5V to (VDD + 0.5V) COIL (pin3)............................................................100mA Lamp Outputs..............................................................................230VPP Storage Temperature....................................................-65˚C to +150˚C Power Dissipation Per Package 8-pin NSOIC (derate 6.14mW/oC above +70oC).................................500mW 8-pin µSOIC (derate 4.85mW/oC above +70oC)..................................390mW SPECIFICATIONS (T= 25°C; VDD = 1.5V; Lamp Capacitance = 8200pFwith 1 00Ω Series resistance; Coil = 470µH at 4 Ohms; COSC = 180pF unless otherwise noted); CINT=1800pF PARAMETER MIN. TYP. MAX. UNITS 1.1 1.5 1.7 V 30 60 mA 1.7 V 0 VDD 0.25V VDD+0.25 V HON Current, EL on 3 15 µA internal pulldown, VHON=VDD=1.5V Shutdown Current, ISD=ICOIL+IDD 1 5 µA VHON=0V Supply Voltage, VDD Supply Current, ICOIL+IDD Coil Voltage, VCOIL HON Input Voltage, VHON LOW: EL off HIGH: EL on V DD -0.25 VDD-0.25 CONDITIONS VHON=VDD=1.5V INDUCTOR DRIVE Coil Frequency, fCOIL=fLAMPx64 Coil Duty Cycle 25.6 kHz 90 % Peak Coil Current, IPK-COIL 90 mA Guaranteed by design. 500 Hz TAMB=+25OC, VDD=1.5V TAMB=-40OC to +85OC, VDD=1.5V VPP TAMB=+25OC, VDD=1.5V TAMB=-40OC to +85OC, VDD=1.5V EL LAMP OUTPUT EL Lamp Frequency, fLAMP 300 400 Peak to Peak Output Voltage 120 90 160 SP4425DS/20 SP4425 Electroluminescent Lamp Driver 2 © Copyright 2000 Sipex Corporation (T= 25°C; VDD = 3.0V; Lamp Capacitance = 4nF with 100Ω Series resistance; Coil = 2mH/44ohms; COSC = 180pF, CINT = 470pF unless otherwise noted) PARAMETER MIN. TYP. MAX. UNITS 2.2 3.0 3.3 V 28 35 mA 3.3 V 0 VDD 0.25V VDD+0.25 V HON Current, EL on 5 20 µA internal pulldown, VHON=VDD=3V Shutdown Current, ISD=ICOIL+IDD 1 8 µA VHON=0V Supply Voltage, VDD Supply Current, ICOIL+IDD VDD Coil Voltage, VCOIL HON Input Voltage, VHON LOW: EL off HIGH: EL on -0.25 VDD-0.25 CONDITIONS VHON=VDD=3V INDUCTOR DRIVE Coil Frequency, fCOIL=fLAMPx64 Coil Duty Cycle 28.8 kHz 90 % Peak Coil Current, IPK-COIL 90 mA Guaranteed by design. 550 775 Hz TAMB=+25OC, VDD=3.0V TAMB=-40OC to +85OC, VDD=3.0V VPP TAMB=+25OC, VDD=2.2V TAMB=+25OC, VDD=3.0V TAMB=-40OC to +85OC, VDD=3.0V EL LAMP OUTPUT EL Lamp Frequency, fLAMP 350 275 450 Peak to Peak Output Voltage 120 170 120 150 190 This data sheet specifies environmental parameters, final test conditions and limits as well suggested operating conditions. For applications which require performance beyond the specified condition and or limits please consult the factory. Bonding Diagram: VDD HON PAD VDD EL1 EL1 EL2 D1 COIL VSS COSC COSC EL2 HON Coil VSS SP4425DS/20 Y 427.0 429.0 28.0 -172.0 -381.0 -412.0 -157.5 402.0 NOTES: 1. Dimensions are in Microns unless otherwise noted. 2. Bonding pads are 125x125 typical. 3. Outside dimensions are maximum, including scribe area. 4. Die thickness is 10 mils +/- 1. 5. Pad center coordinates are relative to die center. 6. Die size 74 x 44 mils. D1 73 x 46 MS666 X 261.0 813.0 813.0 813.0 767.0 143.5 -790.0 -785.5 SP4425 Electroluminescent Lamp Driver 3 © Copyright 2000 Sipex Corporation THEORY OF OPERATION PIN DESCRIPTION 8 7 6 5 SP4425 1 2 3 4 The SP4425 is made up of three basic circuit elements, an oscillator, coil, and switched H-bridge network. The oscillator provides the device with an on-chip clock source used to control the charge and discharge phases for the coil and lamp. An external capacitor connected between pins 1 and VSS allows the user to vary the oscillator frequency. For a given choice of coil inductance there will be an optimum COSC Capacitor value that gives the maximum light output. Pin 1 – COSC- Capacitor input 1, connect Capacitor from VSS to Pin 1 to set COSC frequency. The suggested oscillator frequency is 25.6kHz (COSC=180pF). The oscillator output is internally divided to create the control signal for fLAMP. The oscillator output is internally divided down by 6 flip flops, a 25.6kHz signal will be divided into 6 frequency levels: 12.8kHz, 6.4kHz, 3.2kHz, 1.6kHz, 800Hz, and 400Hz. The oscillator output (25.6kHz) is used to drive the coil (see figure 2 on page 11) and the sixth flip flop output (300Hz) is used to drive the lamp. Although the oscillator frequency can be varied to optimize the lamp output, the ratio of fCOIL/fLAMP will always equal 64. Pin 2 – VSS- Power supply common, connect to ground. Pin 3 – Coil- Coil input, connect coil from VDD to pin 3. Pin 4 – D1- Diode Cathode connection. – CINT- Integrator capacitor, connect capacitor from pin 4 to ground to minimize coil glitch energy. Pin 5 – Lamp- Lamp driver output2, connect to EL lamp. Pin 6 – Lamp- Lamp driver output1, connect to EL lamp. Pin 7 – VDD- Power supply for driver, connect to system VDD. Pin 8 – HON- Enable for driver operation, high = active; low = inactive. The coil is an external component connected from VBATTERY to pin 3 of the SP4425. VBATTERY= 1.5 VDC with a 470µH/4Ω coil are typical conditions. Energy is stored in the coil according to the equation EL=1/2LI2, where I is the peak current flowing in VBATTERY Low ESR decoupling capacitor 470µH/4Ω VDD .1µF CINT=1800pF typ IN4148 7 3 8 HON VDD 4 Coil D1 1MΩ 1 COSC OSC SCR2 SCR1 fCOIL Cap1 180pF fLAMP Q FF1 FF6 Q fLAMP EL2 5 VSS 2 EL1 6 EL Lamp SP4425 Schematic SP4425DS/20 SP4425 Electroluminescent Lamp Driver 4 © Copyright 2000 Sipex Corporation the inductor. The current in the inductor is time dependent and is set by the "ON" time of the coil switch: I=(VL/L)tON, where VL is the voltage across the inductor. At the moment the switch closes, the current in the inductor is zero and the entire supply voltage (minus the VSAT of the switch) is across the inductor. The current in the inductor will then ramp up at a linear rate. As the current in the inductor builds up, the voltage across the inductor will decrease due to the resistance of the coil and the "ON" resistance of the switch: VL=VBATTERYIRL-VSAT. Since the voltage across the inductor is decreasing, the current ramp-rate also decreases which reduces the current in the coil at the end of tON the energy stored in the inductor per coil cycle and therefore the light output. The other important issue is that maximum current (saturation current) in the coil is set by the design and manufacturer of the coil. If the parameters of the application such as VBATTERY, L, RL or tON cause the current in the coil to increase beyond its rated ISAT, excessive heat will be generated and the power efficiency will decrease with no additional light output. The H-bridge consists of two SCR structures that act as high voltage switches. These two switches control the polarity of how the lamp is charged. The SCR switches are controlled by the fLAMP signal which is the oscillator frequency divided by 64. For a 25.6kHz oscillator, fLAMP=400Hz. When the energy from the coil is released, a high voltage spike is created triggering the SCR switches. The direction of current flow is determined by which SCR is enabled. One full cycle of the H-bridge will create a voltage step from ground to 80V (typical) on pins 5 and 6 which are 180 degrees out of phase with each other (see figure 3 on page 11). A differential view of the outputs is shown in figure 4 on page 11. Layout Considerations The SP4425 circuit board layout must observe careful analog precautions. For applications with noisy power supply voltages, a 0.1µF low ESR decoupling capacitor must be connected from Vdd to ground. Any high voltage traces should be isolated from any digital clock traces or enable lines. A solid ground plane connection is strongly recommended. All traces to the coil or to the high voltage outputs should be kept as short as possible to minimize capacitive coupling to digital clock lines and to reduce EMI emissions. The majority of the current goes through the coil and typically less than 2mA is required for VDD of the SP4425. VDD can range from 1.5V to 3.0V; it is not necessary that VDD=VBATTERY. Coils are also a function of the core material and winding used -performance variances may be noticeable from different coil suppliers. The Sipex SP4425 is final tested at 1.5V using a 470µH/4Ω coil from Toko, and a 2mH/44Ω coil from Matsushita at 3V. For suggested coil sources see page 12. Integrator Capacitor An integrating capacitor must be placed from pin 4 (D1) to ground in order to minimize glitches associated with switching the coil. A capacitor at this point will collect the high voltage spikes and will maximize the peak to peak voltage output. High resistance EL lamps will produce more pronounced spiking on the EL output waveform; adding the CINT capacitor will minimize the peaking and increase the voltage output at each coil step. The value of the integrator capacitor is application specific typical values can range from 500pF to 0.1µF. No integrator capacitor or very small values (500pF) will have a minor effect on the output, whereas a 0.1µF capacitor will cause the output to charge and discharge rapidly creating a square wave output. For most applications an 1800pF integrator capacitor is suitable. The fCOIL signal controls a switch that connects the end of the coil at pin 3 to ground or to open circuit. The fCOIL signal is a 90% duty cycle signal switching at the oscillator frequency. During the time when the fCOIL signal is high, the coil is connected from VBATTERY to ground and a charged magnetic field is created in the coil. During the low part of fCOIL , the ground connection is switched open, the field collapses and the energy in the inductor is forced to flow toward the lamp. fCOIL will send 32 of these charge pulses (see figure 2 on page 11) lamp, each pulse increases the voltage drop across the lamp in discrete steps. As the voltage potential approaches its maximum, the steps become smaller (see figure 1 on page 11). SP4425DS/20 SP4425 Electroluminescent Lamp Driver 5 © Copyright 2000 Sipex Corporation The amount of light emitted is a function of the voltage applied to the lamp, the frequency at which it is applied, the lamp material used and its size, and lastly, the inductor used. Both voltage and frequency are directly related to light output. In other words as the voltage or the frequency of the EL output is increased the light output will also increase. The voltage has a much larger impact on light output than the frequency does. For example, an output signal of 168VPP with a frequency of 500Hz can yield 15Cd/m2, in the same application a different EL driver could produce 170VPP with a frequency of 450Hz and can also yield 15Cd/m2. Variations in peak to peak voltage and variations in lamp frequency are to be expected, light output will also vary from device to device however typical light output variations are usually not visually noticeable. Electroluminescent Technology What is electroluminescence? An EL lamp is basically a strip of plastic that is coated with a phosphorous material which emits light (fluoresces) when a high voltage (>40V) which was first applied across it, is removed or reversed. Long periods of DC voltages applied to the material tend to breakdown the material and reduce its lifetime. With these considerations in mind, the ideal signal to drive an EL lamp is a high voltage sine wave. Traditional approaches to achieving this type of waveform included discrete circuits incorporating a transformer, transistors, and several resistors and capacitors. This approach is large and bulky, and cannot be implemented in most hand held equipment. Sipex now offers low power single chip driver circuits specifically designed to drive small to medium sized electroluminescent panels if all that is required is one external inductor fast recovery diode and two capacitors. There are many variables which can be optimized for specific applications. Sipex supplies characterization charts to aid the designer in selecting the optimum circuit configuration (see page 7 and 8). Electroluminescent backlighting is ideal when used with LCD displays, keypads, or other backlit readouts. Its main use is to illuminate displays in dim to dark conditions for momentary periods of time. EL lamps typically consume less than LEDs or bulbs making them ideal for battery powered products. Also, EL lamps are able to evenly light an area without creating "hot spots" in the display. SP4425DS/20 SP4425 Electroluminescent Lamp Driver 6 © Copyright 2000 Sipex Corporation 470µH/4Ω Pager Application VIN=1.5V + HON=VDD=ON HON=0V=OFF COSC =180pF – COSC HON VSS VDD Coil EL1 D1 EL2 0.1µF Low ESR Decoupling Capacitor EL Lamp IN4148 NOTE: Keep coil as close to SP4425 as possible CINT=1800pF 5Ftl 1.5 sq.in. 4nF SP4425 NOTE: Keep high voltage traces short and away from VDD and clock lines Typical SP4425 Application Circuit 470µH/4Ω HON=VDD=ON HON=0V=OFF COSC=180pF VIN=+1.5V COSC HON VSS VDD Coil EL1 D1 EL2 0.1µF Low ESR Decoupling Capacitor 100Ω 5Ftl IN4148 NOTE: Keep coil as close to SP4425 as possible CINT=1800pF 8.2nF SP4425 NOTE: Keep high voltage traces short and away from VDD and clock lines SP4425 1.5V Test Circuit 2mH/44Ω HON=VDD=ON HON=0V=OFF VIN=3V + COSC =180pF – COSC HON VSS VDD Coil EL1 D1 EL2 0.1µF Low ESR Decoupling Capacitor 100Ω 5Ftl IN4148 NOTE: Keep coil as close to SP4425 as possible Cint = 470pF 4nF SP4425 NOTE: Keep high voltage traces short and away from VDD and clock lines SP4425 3V Test Circuit SP4425DS/20 SP4425 Electroluminescent Lamp Driver 7 © Copyright 2000 Sipex Corporation The following performance curves are intended to give the designer a relative scale from which to optimize specific applications. Absolute measurements may vary depending upon the brand of components chosen. VLAMP Peak VLAMP Peak (Volts) 60 65 55 50 45 Inductors µH/DCR 40 A 470/4 35 B 470/11 C 470/4 30 1 1.05 1.1 1.15 1.2 1.25 1.3 1.35 1.4 1.45 VDD (Volts) 1.5 D 470/2.3 E 470/3.4 Lamp = 1.5 sq. in., C1 = 0.1µF, C2 = 180pF, D1 = D1N4148 ITOTAL 50 ITOTAL (Volts) 45 40 35 Inductors µH/DCR 30 A 470/4 25 B 470/11 20 1 1.1 1.3 1.2 1.4 VDD (Volts) 1.5 C 470/4 D 470/2.3 E 470/3.4 Lamp = 1.5 sq. in., C1 = 0.1µF, C2 = 180pF, D1 = D1N4148 SP4425DS/20 SP4425 Electroluminescent Lamp Driver 8 © Copyright 2000 Sipex Corporation The following performance curves are intended to give the designer a relative scale from which to optimize specific applications. Absolute measurements may vary depending upon the brand of components chosen. Light Output (FtL) Light Output 5 4.5 4 3.5 3 2.5 2 1.5 1 0.5 Inductors µH/DCR A 470/4 B 470/11 0 1 1.1 1.2 1.3 1.4 1.5 VDD (Volts) C 470/4 D 470/2.3 E 470/3.4 Lamp = 1.5 sq. in., C1 = 0.1µF, C2 = 180pF, D1 = D1N4148 Lamp Frequency (Hz) Lamp Frequency 380 360 340 320 300 280 260 240 220 200 Inductors µH/DCR A 470/4 B 470/11 1 1.1 1.3 1.2 1.4 1.5 VDD (Volts) C 470/4 D 470/2.3 E 470/3.4 Lamp = 1.5 sq. in., C1 = 0.1µF, C2 = 180pF, D1 = D1N4148 SP4425DS/20 SP4425 Electroluminescent Lamp Driver 9 © Copyright 2000 Sipex Corporation The following performance curves are intended to give the designer a relative scale from which to optimize specific applications. Absolute measurements may vary depending upon the brand of components chosen. 40 35 30 25 20 15 10 5 0 SP4425 Lamp Frequency vs. Temperature Lamp Frequency (Hz) Total Current (mA) SP4425 Total Supply Current vs. Temperature 1.5V 1.1V -40 0 70 25 Temperature ( O C) 700 600 500 400 300 100 0 -40 85 Coil=470µH/4Ω; COSC=180pF; CINT=1800pF; CLOAD=4.7nF Lamp Frequency (Hz) Peak-to-Peak Votage (Volts) 150 100 1.5V 1.1V 50 0 70 25 Temperature ( O C) -40 70 25 Temperature ( O C) 85 Total ICC @3VDD vs. Temperature Total Current (mA) Light Output (cd/m2) 0 Coil=2mH/44Ω; COSC=180pF; CINT=470pF; CLOAD=4nF 25 20 15 10 5 0 70 25 Temperature ( O C) 3.0V 2.2V 100 0 Light Output vs. Temperature 0 85 800 700 600 500 400 300 200 85 Coil=470µH/4Ω; COSC=180pF; CINT=1800pF; CLOAD=4.7nF -40 70 25 Temperature ( O C) Lamp Frequency vs. Temperature 200 0 0 Coil=470µH/4Ω; COSC=180pF; CINT=1800pF; CLOAD=4.7nF Peak-to-Peak Voltage vs. Temperature -40 1.5V 1.1V 200 40 35 30 25 20 15 10 5 0 -40 85 Coil=2mH/44Ω; COSC=180pF; CINT=470pF; VDD=3.0V; Load=3 sq.in. 0 70 25 Temperature ( O C) 85 Coil=2mH/44Ω; COSC=180pF; CINT=470pF; CLOAD=4nF SP4425 Peak-to-Peak Voltage vs. Temperature Peak-to-Peak Votage (Volts) 250 200 150 100 3.0V 2.2V 50 0 -40 0 70 25 Temperature ( O C) 85 Coil=2mH/44Ω; COSC=180pF; CINT=470pF; CLOAD=4nF SP4425DS/20 SP4425 Electroluminescent Lamp Driver 10 © Copyright 2000 Sipex Corporation V PEAK =80V (typical) EL1 output; 32 charge steps per half cycle Figure 1. EL output voltage in discrete steps at EL1 output 32 coil pulses per half cycle; 94% duty cycle. Figure 2. Voltage pulses released from the coil to the EL driver circuitry EL1 Output -EL2 Output Figure 3. EL voltage waveforms from the EL1 and EL2 outputs EL1 Output VPP = 160V (typical) -EL2 Output Differential representation (EL1-EL2) Figure 4. El differential output waveform of the EL1 and EL2 outputs SP4425DS/20 SP4425 Electroluminescent Lamp Driver 11 © Copyright 2000 Sipex Corporation The coil part numbers presented in this data sheet have been qualified as being suitable for the SP4425 product. Contact Sipex for applications assistance in choosing coil values not listed in this data sheet. Coil Manufacturers Coilcraft USA Ph: (847) 639-6400 Fax: (847) 639-1469 Coilcraft Taiwan Ph: 886/2/264-3646 Fax: 886/2/270-0294 Coilcraft Europe Ph: 44 01236 730595 Fax: 44 01236 730627 Coil Craft Singapore Ph: 65 296-6933 Fax: 465 296-4463 #382 New Coils .155 .260 Max 6.60 Coilcraft Hong Kong Ph: 852 770-9428 Fax: 852 770-0729 Dia .115 .175 Max Max Part No. DO1608C-474 470µH, 3.60 ohm (All Dimensions in mm) muRata Taiwan Electronics muRata Hong Kong Ph: 011 88642914151 Ph: 011-85223763898 Fax: 011 88644252929 Fax: 011 852237555655 muRata Europe Ph: 011-4991166870 Fax: 011-49116687225 muRata Electronics Singapore Ph: 011 657584233 Fax: 011 657536181 5.0 ±0.3 5.0 ±0.3 4.7 ±0.3 muRata USA Ph: (770) 436-1300 Fax: (770) 436-3030 Part No. LQN4N471K04 470µH, 11.5 ohm 5.7 ±0.3 (All Dimensions in mm) KOA Speer Electronics, Inc. Ph: 814-362-5536 Fax: 814-362-8883 4.5 ± 4.0 ± 0.2 Part No. LPC4045TE471K 470µH, 4.55 ohm 4.5 Max (All Dimensions in mm) Sumida Electric Co., LTD. USA Ph: (847) 956-0666 Fax: (847) 956-0702 Sumida Electric Co., LTD. Singapore Ph: 2963388 Fax: 2963390 Sumida Electric Co., LTD. Japan Ph: 03-3607-5111 Fax: 03-3607-5144 Sumida Electric Co., LTD. Hong Kong Ph: 28806688 Fax: 25659600 7.3 ±0.2 7.3 4.5 Max Part No. CDRH74-471MC 470µH, 3.01 ohm (All Dimensions in mm) Toko America Inc. USA Ph: (847) 297-0070 Fax: (847) 699-7864 Toko Inc. Japan Ph: 03 3727 1161 Fax: 03 3727 1176 Toko Inc. Europe Ph: (0211) 680090 Fax: (0211) 679-9567 Toko Inc. Singapore Ph: (255) 4000 Fax: (250) 8134 Toko Inc. Hong Kong Ph: 2342-8131 Fax: 2341-9570 Part No. 667MA471N 470µH, 1.90 ohm 4.4 Max 2.75 Max 4.4 Max (All Dimensions in mm) EL polarizers/transflector manufacturers Nitto Denko San Jose, CA Phone: (510) 445-5400 Astra Products Baldwin, NJ Phone: (516) 223-7500 Fax: (516) 868-2371 SP4425DS/20 EL Lamp manufacturers Metro Mark/Leading Edge Minnetonka, MN Phone: (800) 680-5556 Fax: (612) 935-5718 NEC Corporation Tokyo, Japan Phone: (03) 3798-9572 Fax: (03) 3798-6134 Midori Mark Ltd. 1-5 Komagata 2-Chome Taita-Ku 111-0043 Japan Phone: 81-03-3848-2011 Seiko Precision Chiba, Japan Phone: (03) 5610-7089 Fax: (03) 5610-7177 Luminescent Systems Inc. (LSI) 4 Lucent Drive Lebanon, NH 03766 Phone: (603) 643-7766 Fax: (603) 643-5947 Gunze Electronics 2113 Wells Branch Parkway Austin, TX 78728 Phone: (512) 752-1299 Fax: (512) 252-1181 SP4425 Electroluminescent Lamp Driver 12 © Copyright 2000 Sipex Corporation All package dimensions in inches 8-pin µSOIC 8-pin NSOIC 0.0256 BSC 12.0˚ ±4˚ 0.012 ±0.003 0.189/0.197 SP4425CN 0.150/0.157 0.228/0.244 0.0965 ±0.003 0.053/0.069 R .003 SP4425CU 0.118 ±0.002 0.016 ±0.003 0.014/0.019 0.050 BSC 1 0.008 12.0˚ ±4˚ 0.01 0.020 0.020 1 3.0˚ ±3˚ 0.0215 ±0.006 0.037 Ref 2 0.116 ±0.004 0.034 ±0.002 0.116 ±0.004 0.040 ±0.002 0.013 ±0.005 0.118 ±0.002 95 SP4425CN per tube, no minimum quantity 0˚ - 6˚ 0.006 ±0.006 0.006 ±0.006 0.118 ±0.004 0.004 ±0.002 50 SP4425CU per tube P W NSOIC-8 13" reels: P=8mm, W=12mm µSOIC-8 13" reels: P=8mm, W=12mm Pkg. CN CU SP4425DS/20 Minimum qty per reel Standard qty per reel Maximum qty per reel 500 500 2500 2500 3000 3000 SP4425 Electroluminescent Lamp Driver 13 © Copyright 2000 Sipex Corporation ORDERING INFORMATION Model Operating Temperature Range Package Type SP4425CN . ............................................ -40˚C to +85˚C ......................................... 8-Pin NSOIC SP4425CU . ............................................ -40˚C to +85˚C ......................................... 8-Pin µSOIC SP4425CX .............................................. -40˚C to +85˚C ........................................................ Die SP4425NEB ..................................................... N/A ............................... NSOIC Evaluation Board SP4425UEB ..................................................... N/A ............................... µSOIC Evaluation Board Please consult the factory for pricing and availability on a Tape-On-Reel option. Corporation SIGNAL PROCESSING EXCELLENCE Sipex Corporation Headquarters and Sales Office 22 Linnell Circle Billerica, MA 01821 TEL: (978) 667-8700 FAX: (978) 670-9001 e-mail: [email protected] Sales Office 233 South Hillview Drive Milpitas, CA 95035 TEL: (408) 934-7500 FAX: (408) 935-7600 Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the application or use of any product or circuit described hereing; neither does it convey any license under its patent rights nor the rights of others. SP4425DS/20 SP4425 Electroluminescent Lamp Driver 14 © Copyright 2000 Sipex Corporation