EP5352Q/EP5362Q/EP5382Q 500/600/800mA Synchronous Buck Regulators With Integrated Inductor RoHS Compliant VIN Product Overview UVLO Thermal Limit Current Limit ENABLE Soft Start P-Drive (-) Logic VOUT PWM Comp (+) N-Drive GND VSENSE Sawtooth Generator Compensation Network (-) Switch Error Amp VFB (+) DAC VREF Voltage Select The Ultra-Low-Profile EP53X2Q product family is targeted to applications where board area and profile are critical. EP53X2Q is a complete power conversion solution requiring only two low cost ceramic MLCC caps. Inductor, MOSFETS, PWM, and compensation are integrated into a tiny 5mm x 4mm x 1.1mm QFN package. The EP53x2Q family is engineered to simplify design and to minimize layout constraints. High switching frequency and internal type III compensation provides superior transient response. With a 1.1 mm profile, the EP53x2 is perfect for space and height limited applications. A 3-pin VID output voltage select scheme provides seven pre-programmed output voltages along with an option for external resistor divider. Output voltage can be programmed on-the-fly to provide fast, dynamic voltage scaling. Package Boundry VS0 VS1 VS2 Product Highlights • Revolutionary integrated inductor • Very small solution foot print* • Fully RoHS compliant; MSL 3 260°C reflow • Only two low cost components required • 5mm x 4mm x1.1mm QFN package • Wide 2.4V to 5.5V input range • 500, 600, 800 mA output current versions • Less than 1 μA standby current • 4 MHz switching frequency • Fast transient response • Very low ripple voltage; 5mVp-p typical • 3 Pin VID Output Voltage select • External divider option • Dynamically adjustable output • Designed for Low noise/EMI • Short circuit, UVLO, and thermal protection Typical Application Circuit VSense ENABLE VIN Vin 2.2uF Voltage Select VOUT Vout 10μF VFB VS0 VS1 VS2 GND Figure 1. Typical application circuit. Applications • • • • • • Area constrained applications Mobile multimedia, smartphone & PDA Mobile and Cellular platforms VoIP and Video phones Personal Media Players FPGA, DSP, IO & Peripherals *Optimized PCB layout Gerber files downloadable from the Enpirion website to assure first pass design success. 03132 4/28/2009 Rev:B EP5382Q/EP5362Q/EP5352Q Absolute Maximum Ratings CAUTION: Absolute Maximum ratings are stress ratings only. Functional operation beyond recommended operating conditions is not implied. Stress beyond absolute maximum ratings may cause permanent damage to the device. Exposure to absolute maximum rated conditions for extended periods may affect device reliability. PARAMETER SYMBOL VIN Input Supply Voltage Voltages on: ENABLE, VSENSE, VS0-VS2 Voltage on: VFB Storage Temperature Range Reflow Temp, 10 Sec, MSL3 JEDEC J-STD-020A ESD Rating (based on Human Body Model) TSTG MIN -0.3 -0.3 -0.3 -65 MAX 7.0 VIN + 0.3 2.7 150 260 2000 UNITS V V V °C °C V Recommended Operating Conditions PARAMETER Input Voltage Range Output Voltage Range Operating Ambient Temperature Operating Junction Temperature SYMBOL VIN VOUT TA TJ MIN 2.4 0.6 -40 -40 MAX 5.5 VIN-0.45 +85 +125 UNITS V V °C °C Thermal Characteristics PARAMETER Thermal Resistance: Junction to Ambient (0 LFM) Thermal Resistance: Junction to Case (0 LFM) Thermal Shutdown Thermal Shutdown Hysteresis SYMBOL θJA θJC TJ-TP TYP 65 15 +150 15 UNITS °C/W °C/W °C °C Electrical Characteristics NOTE: TA = 25°C unless otherwise noted. Typical values are at VIN = 3.6V. EP5352QI, EP5362QI: CIN = 2.2μF, COUT=10uF. EP5382QI: CIN = 4.7μF, COUT=10uF. PARAMETER Operating Input Voltage Under Voltage Lockout UVLO Hysteresis SYMBOL VIN VUVLO VOUT Initial Accuracy VOUT VOUT Variation for all Causes VOUT Feedback Pin Voltage VFB Feedback Pin Input Current IFB Feedback Pin Voltage VFB Dynamic Voltage Slew Rate Vslew ©Enpirion 2009 all rights reserved, E&OE 03132 TEST CONDITIONS MIN 2.4 MAX 5.5 2.3 UNITS V V V -2.0 +2.0 % -3.0 +3.0 % VIN going low to high 2.4V ≤ VIN ≤ 5.5V, ILOAD = 100mA; TA = 25C 2.4V ≤ VIN ≤ 5.5V, ILOAD = 0 - 1A, TA = -40°C to +85°C 2.4V ≤ VIN ≤ 5.5V, ILOAD = 100mA VSO=VS1=VS2=1 TYP 2.2 0.145 0.591 0.603 0.615 1 2.4V ≤ VIN ≤ 5.5V, ILOAD = 0-800mA, TA = -40°C to +85°C VSO=VS1=VS2=1 0.585 2 4/28/2009 nA 0.603 3 V 0.621 V mV/μS www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q PARAMETER Continuous Output Current EP5352QI Continuous Output Current EP5362QI Continuous Output Current EP5382QI Shut-Down Current Quiescent Current PFET OCP Threshold VS0-VS1 Voltage Threshold VS0-VS2 Pin Input Current SYMBOL TYP MAX UNITS EP5352Q 500 mA IOUT EP5362Q 600 mA IOUT EP5382Q 800 mA ISD Enable = Low No switching 2.4V ≤ VIN ≤ 5.5V, 0.6V ≤ VOUT ≤ VIN – 0.6V Pin = Low Pin = High ILIM 1.4 IEN FOSC RDS(ON) RDS(ON) Tss 0.75 800 μA μA 2 A 0.0 1.4 IVSX ©Enpirion 2009 all rights reserved, E&OE 03132 MIN IOUT Enable Voltage Threshold Enable Pin Input Current Operating Frequency PFET On Resistance NFET On Resistance Internal Inductor DCR Soft-Start Operation Time to 90% Vout TEST CONDITIONS 0.4 VIN 1 Logic Low Logic High VIN = 3.6V nA 0.0 1.4 Vout = 3.3V 3 4/28/2009 V 0.2 VIN V 2 4 340 270 .110 μA MHz mΩ mΩ Ω 1 mS www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q VFB VIN 2 15 VSENSE GND 3 14 GND 4 VOUT VOUT VS0 ENABLE 19 20 VFB 16 VSENSE 15 NC NC 14 3 GND 13 NC NC 13 4 GND 5 12 NC NC 12 5 VOUT 6 11 NC NC 11 6 VOUT 8 7 NC VOUT NC NC 10 NC 9 9 NC NC 8 VOUT 10 7 VIN (Pin 1,2): Input voltage pin. Supplies power to the IC. VIN can range from 2.4V to 5.5V. 1 VIN 2 VIN VFB (Pin 16): Feed back pin for external divider option. When using the external divider option (VS0=VS1=VS2= high) connect this pin to the center of the external divider. Set the divider such that VFB = 0.603V. Input GND: (Pin 3): Input power ground. Connect this pin to the ground terminal of the input capacitor. Refer to Layout Recommendations for further details. VS0,VS1,VS2 (Pin 17,18,19): Output voltage select. VS0=pin19, VS1=pin18, VS2=pin17. Selects one of seven preset output voltages or choose external divider by connecting pins to logic high or low. Logic low is defined as VLOW ≤ 0.4V. Logic high is defined as VHIGH ≥ 1.4V. Any level between these two values is indeterminate. (refer to section on output voltage select for more detail). Output GND: (Pin 4): Power ground. The output filter capacitor should be connected to this pin. Refer to Layout recommendations for further detail. VOUT (Pin 5,6,7): Regulated output voltage. NC (Pin 8,9,10,11,12,13,14): These pins should not be electrically connected to each other or to any external signal, voltage, or ground. One or more of these pins may be connected internally. ENABLE (Pin 20): Output enable. Enable = logic high, disable = logic low. Logic low is defined as VLOW ≤ 0.2V. Logic high is defined as VHIGH ≥ 1.4V. Any level between these two values is indeterminate. VSENSE (Pin 15): Sense pin for output voltage regulation. Connect VSENSE to the output voltage rail as close to the terminal of the output filter capacitor as possible. ©Enpirion 2009 all rights reserved, E&OE Thermal Pad Figure 3. Pin description, bottom view. Figure 2. Pin description, top view. 03132 VS1 VS2 17 16 18 VS1 18 1 VS2 VS0 19 VIN 17 ENABLE 20 Pin Description Thermal Pad. Thermal pad to remove heat from package. Connect to surface ground pad and PCB internal ground plane. 4 4/28/2009 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q Functional Block Diagram VIN UVLO Thermal Limit Current Limit ENABLE Soft Start P-Drive (-) Logic VOUT PWM Comp (+) N-Drive GND VSENSE Sawtooth Generator Compensation Network (-) Switch Error Amp VFB (+) DAC Voltage Select VREF Package Boundry VS0 VS1 VS2 Figure 4. Functional block diagram. ©Enpirion 2009 all rights reserved, E&OE 03132 5 4/28/2009 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q Typical Performance Characteristics Efficiency vs Output Current Efficiency vs Output Current Efficiency -% 95 100 90 95 85 90 85 Efficiency -% 80 V OUT = 3.3V 75 V OUT = 3.0V 70 V OUT = 2.7V 65 V OUT = 2.5V 80 V OUT = 3.3V 75 V OUT = 3.0V 70 V OUT = 2.7V V OUT = 2.5V 65 V OUT = 1.8V 60 V OUT = 1.8V 60 55 VIN = 5.0V 55 50 50 150 250 350 450 V IN = 3.6V 50 550 50 150 Load Current (mA) 250 350 450 550 Load Current (mA) Start up Waveform Efficiency vs Output Current 100 95 V out 1V/Div 90 Efficiency -% 85 80 75 70 V OUT = 3.0V V OUT = 2.7V 65 V OUT = 2.5V 60 Enable 2V/Div V OUT = 1.8V 55 V OUT = 1.2V VIN = 3.3V 50 50 150 250 350 450 VIN = 5.0V VOUT = 3.3V 550 Load Current (mA) Transient Response Transient Response Vout 50mV/Div Vout 50mV/Div ILoad 500mA/Div ILoad 500mA/Div VIN = 3.3V 20μs/Div VOUT = 1.8V Iload = 100mA to 800mA VIN = 5.0V 20μs/Div VOUT = 3.3V Iload = 100mA to 800mA Output Ripple V out 10mV/Div Output Ripple V out 10mV/Div VIN = 3.6V 200ns/Div VOUT = 3.3V Output Cap = 2 x 10 μF 0805 V IN = 3.6V 200ns/Div V OUT = 3 .3V Output Cap = 10 μF 0805 ©Enpirion 2009 all rights reserved, E&OE 03132 200μs/Div 6 4/28/2009 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q Detailed Description Protection features include under-voltage lockout (UVLO), over-current protection (OCP), short circuit protection, and thermal overload protection. Functional Overview The EP53x2Q family is a complete DCDC converter solution requiring only two low cost MLCC capacitors. MOSFET switches, PWM controller, Gate-drive, compensation, and inductor are integrated into the tiny 5mm x 4mm x 1.1mm package to provide the smallest footprint possible while maintaining high efficiency and high performance. The converter uses voltage mode control to provide the simplest implementation and high noise immunity. The device operates at a 4 MHz switching frequency. The high switching frequency allows for a wide control loop bandwidth providing excellent transient performance. The 4 MHz switching frequency enables the use of very small components making possible this unprecedented level of integration. Integrated Inductor Enpirion has introduced the world’s first product family featuring integrated inductors. The EP53x2Q family utilizes a low loss, planar construction inductor. The use of an internal inductor localizes the noises associated with the output loop currents. The inherent shielding and compact construction of the integrated inductor reduces the radiated noise that couples into the traces of the circuit board. Further, the package layout is optimized to reduce the electrical path length for the AC ripple currents that are a major source of radiated emissions from DCDC converters. The integrated inductor significantly reduces parasitic effects that can harm loop stability, and makes layout very simple. Enpirion’s proprietary power MOSFET technology provides very low switching loss at frequencies of 4 MHz and higher, allowing for the use of very small internal components, and very wide control loop bandwidth. Unique magnetic design allows for integration of the inductor into the very low profile 1.1mm package. Integration of the inductor virtually eliminates the design/layout issues normally associated with switch-mode DCDC converters. All of this enables much easier and faster integration into various applications to meet demanding EMI requirements. Soft Start Internal soft start circuits limit in-rush current when the device starts up from a power down condition or when the “ENABLE” pin is asserted “high”. Digital control circuitry limits the VOUT ramp rate to levels that are safe for the Power MOSFETS and the integrated inductor. The soft start ramp rate is nominally 3.3mV/μSec. Output voltage is chosen from seven preset values via a three pin VID voltage select scheme. An external divider option enables the selection of any voltage in the 0.6 to VIN Vdropout. This reduces the number of components that must be qualified and reduces inventory problems. The VID pins can be toggled on the fly to implement glitch free dynamic voltage scaling. ©Enpirion 2009 all rights reserved, E&OE 03132 Over Current/Short Circuit Protection The current limit function is achieved by sensing the current flowing through a sense PMOSFET which is compared to a reference current. When this level is exceeded the PFET is turned off and the N-FET is turned on, pulling VOUT low. This condition is maintained for a period of 1mS and then a normal soft start is initiated. If the over current condition still persists, this cycle will repeat in a “hiccup” mode. 7 4/28/2009 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q and cause it to shut down. A logic high will enable the converter into normal operation. In shutdown mode, the device quiescent current will be less than 1 uA. The ENABLE pin must not be left floating. Under Voltage Lockout During initial power up an under voltage lockout circuit will hold-off the switching circuitry until the input voltage reaches a sufficient level to insure proper operation. If the voltage drops below the UVLO threshold the lockout circuitry will again disable the switching. Hysteresis is included to prevent chattering between states. Thermal Shutdown When excessive power is dissipated in the chip, the junction temperature rises. Once the junction temperature exceeds the thermal shutdown temperature the thermal shutdown circuit turns off the converter output voltage thus allowing the device to cool. When the junction temperature decreases by 15C°, the device will go through the normal startup process. Enable The ENABLE pin provides a means to shut down the converter or enable normal operation. A logic low will disable the converter Application Information Output Voltage Select Table 1. Voltage select settings. To provide the highest degree of flexibility in choosing output voltage, the EP53x2Q family uses a 3 pin VID, or Voltage ID, output voltage select arrangement. This allows the designer to choose one of seven preset voltages, or to use an external voltage divider. Internally, the output of the VID multiplexer sets the value for the voltage reference DAC, which in turn is connected to the non-inverting input of the error amplifier. This allows the use of a single feedback divider with constant loop gain and optimum compensation, independent of the output voltage selected. VS2 0 0 0 0 1 1 1 1 03132 VS0 0 1 0 1 0 1 0 1 VOUT 3.3 2.5 2.8 1.2 3.0 1.8 2.7 External External Voltage Divider Table 1 shows the various VS0-VS2 pin logic states and the associated output voltage levels. A logic “1” indicates a connection to VIN or to a “high” logic voltage level. A logic “0” indicates a connection to ground or to a “low” logic voltage level. These pins can be either hardwired to VIN or GND or alternatively can be driven by standard logic levels. Logic low is defined as VLOW ≤ 0.4V. Logic high is defined as VHIGH ≥ 1.4V. Any level between these two values is indeterminate. These pins must not be left floating. ©Enpirion 2009 all rights reserved, E&OE VS1 0 0 1 1 0 0 1 1 As described above, the external voltage divider option is chosen by connecting the VS0, VS1, and VS2 pins to VIN or logic “high”. The EP53x2Q uses a separate feedback pin, VFB, when using the external divider. VSENSE must be connected to VOUT as indicated in Figure 5. 8 4/28/2009 www.enpirion.com Rev:B VSense ENABLE VIN Vin VOUT Vout 2.2uF 4.7uF EP5382Q/EP5362Q/EP5352Q formulation. Y5V or equivalent dielectric formulations lose capacitance with frequency, bias, and with temperature, and are not suitable for switch-mode DC-DC converter input and output filter applications. Ra 10μF VFB VS0 VS1 Rb VS2 The output capacitance requirement is a minimum of 10uF. The control loop is designed to be stable with up to 60uF of total output capacitance without requiring modification of the control loop. Capacitance above the 10uF minimum should be added if the transient performance is not sufficient using the 10uF. Enpirion recommends a low ESR MLCC type capacitor be used. The output capacitor must use a X5R or X7R or equivalent dielectric formulation. Y5V or equivalent dielectric formulations lose capacitance with frequency, bias, and temperature and are not suitable for switch-mode DC-DC converter input and output filter applications. GND Figure 5. External Divider. The output voltage is selected by the following formula: VOUT = 0.603V (1 + Ra Rb ) Ra must be chosen as 200KΩ to maintain loop gain. Then Rb is given as: Rb = 1.2 x105 Ω VOUT − 0.603 Cin Manufacturer Part # Murata GRM21BR71A225KA01L GRM31MR71A225KA01L GRM21BR70J225KA01L Dynamically Adjustable Output Panasonic The EP53x2Q are designed to allow for dynamic switching between the predefined VID voltage levels The inter-voltage slew rate is optimized to prevent excess undershoot or overshoot as the output voltage levels transition. The slew rate is identical to the softstart slew rate of 3.3mV/uS. Taiyo Yuden Panasonic Input and Output Capacitors Taiyo Yuden The input capacitance requirement is as follows: EP5352Q, EP5362Q = 2.2uF EP5382Q = 4.7uF Enpirion recommends that a low ESR MLCC capacitor be used. The input capacitor must use a X5R or X7R or equivalent dielectric ©Enpirion 2009 all rights reserved, E&OE 03132 9 4/28/2009 10V 6.3V LMK107BJ225KA-T LMK212BJ225KG-T Value 4.7uF WVDC 10V Case Size 0805 1206 0805 1206 6.3V 10V 6.3V Value 10uF 0805 1206 0805 0603 0805 10V LMK212BJ475KG-T LMK316BJ475KD-T JMK212BJ475KD-T Case Size 0805 1206 0805 10V 6.3V ECJ-2FB1A475K ECJ-3YB1A475K ECJ-2FB0J475K ECJ-3YB0J475K Cout Manufacturer Part # Murata GRM219R60J106KE19D GRM319R60J106KE01D WVDC 10V 6.3V ECJ-2FB1A225K ECJ-3YB1A225K ECJ-2YB0J225K Cin Manufacturer Part # Murata GRM219R61A475KE19D GRM319R61A475KA01D GRM219R60J475KE01D GRM31MR60J475KA01L Dynamic transitioning between internal VID settings and the external divider is not allowed. Value 2.2uF 0805 1206 0805 1206 0805 1206 0805 WVDC 6.3V Case Size 0805 1206 Panasonic ECJ-2FB0J106K ECJ-3YB0J106K 6.3V 0805 1206 Taiyo Yuden JMK212BJ106KD-T JMK316BJ106KF-T 6.3V 0805 1206 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q LAYOUT CONSIDERATIONS* *Optimized PCB Layout file downloadable from the Enpirion Website to assure first pass design success Recommendation 1: Input and output filter capacitors should be placed as close to the EP53x2QI package as possible to reduce EMI from input and output loop AC currents. This reduces the physical area of the Input and Output AC current loops. Recommendation 2: DO NOT connect GND pins 3 and 4 together. Pin 3 should be used for the Input capacitor local ground and pin 4 should be used for the output capacitor ground. The ground pad for the input and output filter capacitors should be isolated ground islands and should be connected to system ground as indicated in recommendation 3 and recommendation 5. Recommendation 3: Multiple small vias (0.25mm after copper plating) should be used to connect ground terminals of the Input capacitor and the output capacitor to the system ground plane. This provides a low inductance path for the high-frequency AC currents, thereby reducing ripple and suppressing EMI (see Fig. 5, Fig. 6, and Fig. 7). Recommendation 4: The large thermal pad underneath the component must be connected to the system ground plane through as many thermal vias as possible. The vias should use 0.33mm drill size with minimum one ounce copper plating (0.035mm plating thickness). This provides the path for heat dissipation from the converter. Recommendation 5: The system ground plane referred to in recommendations 3 and 4 should be the first layer immediately below the surface layer (PCB layer 2). This ground plane should be continuous and un-interrupted below the converter and the input and output capacitors that carry large AC currents. If it is not possible to make PCB layer 2 a continuous ground plane, an uninterrupted ground “island” should be created on PCB layer 2 immediately underneath the EN5312QI and its input and output capacitors. The vias that connect the input and output capacitor grounds, and the thermal pad to the ground island, should continue through to the PCB GND layer as well. Recommendation 6: As with any switch-mode DC/DC converter, do not run sensitive signal or control lines underneath the converter package. Figure 6 shows an example schematic for the EP53x2Q using the internal voltage select. In this example, the device is set to a VOUT of 1.2V (VS2=0, VS1=1, VS0=1). ©Enpirion 2009 all rights reserved, E&OE 03132 10 4/28/2009 www.enpirion.com Rev:B VS2 VFB VSENSE NC NC NC NC 16 15 14 13 12 11 EP5382Q/EP5362Q/EP5352Q 17 9 NC 8 NC 7 VOUT 6 5 VOUT 4 GND NC VOUT 3 GND AGND 20 2 ENABLE 1 VS0 19 VIN 18 VIN VS1 10 VOUT VIN 4.7uF/2.2uF 10μF (see layout recommendation 3) Figure 6. Example application, Vout=1.2V. 10 NC 9 NC 8 NC VSENSE NC NC NC NC 15 14 13 12 11 VFB Ra=200K 6 5 VOUT Rb=60K VOUT VOUT VIN 4 7 GND 20 3 ENABLE 2 19 VIN VS0 GND VS1 18 AGND 17 1 VS2 16 Figure 7 shows an example schematic using an external voltage divider. VS0=VS1=VS2= “1”. The resistor values are chosen to give an output voltage of 2.6V. VOUT VIN 4.7uF 10μF (see layout recommendation 3) Figure 7. Schematic showing the use of external divider option, Vout = 2.6V. Figure 8 shows two example board layouts. Note the placement of the input and output capacitors. They are placed close to the device to minimize the physical area of the AC current loops. Note the placement of the vias per recommendation 3. ©Enpirion 2009 all rights reserved, E&OE 03132 11 4/28/2009 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q Package Outline Thermal Vias to Ground Plane CIN COUT Vias to Ground Plane Figure 8. Example layout showing PCB top layer, as well as demonstrating use of vias from input, output filter capacitor local grounds, and thermal pad, to PCB system ground. Design Considerations for Lead-Frame Based Modules Exposed Metal on Bottom Of Package Enpirion has developed a break-through in package technology that utilizes the lead frame as part of the electrical circuit. The lead frame offers many advantages in thermal performance, in reduced electrical lead resistance, and in overall foot print. However, it does require some special considerations. As part of the package assembly process, lead frame construction requires that for mechanical support, some of the lead-frame metal be exposed at the point where wire-bond or internal passives are attached. This results in several small pads being exposed on the bottom of the package. Only the large thermal pad and the perimeter pads are to be mechanically or electrically connected to the PC board. The PCB top layer under the EP53x2QI should be clear of any metal except for the large thermal pad. The “grayed-out” area in Figure 9 represents the area that should be clear of any metal (traces, vias, or planes), on the top layer of the PCB. NOTE: Clearance between the various exposed metal pads, the thermal ground pad, and the perimeter pins, meets or exceeds JEDEC requirements for lead frame package construction (JEDEC MO-220, Issue J, Date May 2005). The separation between the large thermal pad and the nearest adjacent metal pad or pin is a minimum of 0.20mm, including tolerances. This is shown in Figure 10. ©Enpirion 2009 all rights reserved, E&OE 03132 12 4/28/2009 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q Thermal Pad. Connect to Ground plane Figure 9. Exposed metal and mechanical dimensions of the package . Gray area represents bottom metal no-connect and area that should be clear of any traces, planes, or vias, on the top layer of the PCB. 0.25 0.25 0.20 0.20 0.20 JEDEC minimum separation = 0.20 Figure 10. Exposed pad clearances; the Enpirion lead frame package complies with JEDEC requirements. ©Enpirion 2009 all rights reserved, E&OE 03132 13 4/28/2009 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q Figure 11. Recommended PCB Solder Mask Openings. ©Enpirion 2009 all rights reserved, E&OE 03132 14 4/28/2009 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q Figure 12. Package mechanical dimensions. ©Enpirion 2009 all rights reserved, E&OE 03132 15 4/28/2009 www.enpirion.com Rev:B EP5382Q/EP5362Q/EP5352Q Contact Information Enpirion, Inc. 685 US Route 202/206 Suite 305 Bridgewater, NJ 08807 Phone: 908-575-7550 Fax: 908-575-0775 Enpirion reserves the right to make changes in circuit design and/or specifications at any time without notice. Information furnished by Enpirion is believed to be accurate and reliable. Enpirion assumes no responsibility for its use or for infringement of patents or other third party rights, which may result from its use. Enpirion products are not authorized for use in nuclear control systems, as critical components in life support systems or equipment used in hazardous environment without the express written authority from Enpirion. ©Enpirion 2009 all rights reserved, E&OE 03132 16 4/28/2009 www.enpirion.com Rev:B