AMC7580-ADJP

AMC DOC. #: AMC7580_E (LF) Feb 2005 ® ADD MICROTECH CORP. DESCRIPTION AMC7580 7A LOW DROPOUT REGULATOR FEATURES The AMC7580 is a high performance low dropout regulator rated for 7A output current with fixed 2.5V/3.3V/5.0V and adjustable output. It is designed for use in applications requiring low dropout characteristics over the rated current range. When the second low-current input voltage is applied, the drop out voltage can be as low as 100mV at light loads and up to 500mV at maximum output current. On chip trimming adjusts the reference voltage to 1%. These features are ideal for low voltage microprocessor applications requiring a regulated 2.5V to 3.6V power supply. In addition, the AMC7580 provides the device protections including over current and thermal shutdown. The AMC7580 series are ideal to the next generation microprocessor on motherboards where both 5V and 3.3V are available. APPLICATIONS Input-Output differential of typical 500mV at 7A and low quiescent current Output current is excess of 7A Remote sense pin available Reverse battery protection Short circuit protection Internal thermal overload protection Available in 5L plastic TO-220 and surface mount 5L TO-263 packages Pin assignment identical to EZ1585 series. PACKAGE PIN OUT VPOWER VCONTROL VOUT Gnd/Adj SENSE Pentium® Processor Supplies PowerPCTM Supplies Computer Add-On Cards Other Applications Requiring Low Dropout Voltage Over Rated Current. AMC7580-2.5 – 2.5V Fixed AMC7580-3.3 – 3.3V Fixed AMC7580-5.0 – 5.0V Fixed AMC7580-ADJ – Adjustable 5-Pin Plastic TO-220 (Top View) VPOWER VCONTROL VOUT Gnd/Adj SENSE 5-Pin Plastic TO-263 Surface Mount (Top View) ORDER INFORMATION Plastic TO-263 Plastic TO-220 DD 5-pin 5-pin 0 to 70 AMC7580-X.XP AMC7580-X.XDD 0 to 70 AMC7580-X.XPF (Lead Free) AMC7580-X.XDDF (Lead Free) 0 to 70 AMC7580-ADJP AMC7580-ADJDD 0 to 70 AMC7580-ADJPF (Lead Free) AMC7580-ADJDDF (Lead Free) Note: 1.All surface-mount packages are available in Tape & Reel. Append the letter “T” to part number (i.e., AMC7580-X.XDDT). 2.The letter “F” is marked for Lead Free process. TA (OC) P Copyright © 2002, ADD Microtech Corp. 1 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR TYPICAL APPLICATION 1 Power In Control In C1 33µF Ground 5 4 SENSE VPOW ER VCONTROL Gnd C2 10µF 2 C3 68µF VOUT 3 X.XV Output AMC7580-X.X application schematic Power In Control In C1 33µF Ground SENSE VPOW ER VOUT VCONTROL ADJ C2 10µF R1 1% R2 1% C3 68µF Output VOUT = VREF (1+(R2/R1)) + IADJR2 AMC7580-ADJ application schematic Copyright © 2002, ADD Microtech Corp. 2 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR (Note 1) 7V 13V 150 OC -65 OC to 150 OC 300 OC ABSOLUTE MAXIMUM RATINGS Input Voltage (Vpower) Input Voltage (Vcontrol) Operating Junction temperature Storage Temperature Range Lead temperature (Soldering, 10 seconds) Note 1: Exceeding these ratings could cause damage to the device. All voltages are with respect to Ground. Currents are positive into, negative out of the specified terminal. POWER DISSIPATION TABLE Derating factor ( mW/OC ) TA ≤ 25 OC TA=70 OC O T A ≥ 25 C Power rating(mW) Power rating(mW) 22.2 22.2 22.2 2775 2775 2775 1776 1776 1776 Package P PF DD θJA ( C/W ) O TA= 85 OC Power rating (mW) 1443 1443 1443 1443 45 45 45 DDF 45 22.2 2775 1776 Note : 1. θJA: Thermal Resistance-Junction to Ambient, DF : Derating factor, Po: Power consumption. Junction Temperature Calculation: TJ = TA + (PD × θJA), Po = DF × ( Tj- TA) The θJA numbers are guidelines for the thermal performance of the device/PC-board system. All of the above assume no ambient airflow. 2. θJT: Thermal Resistance-Junction to Tab, TC: case(Tab) temperature, TJ = TC + (PD × θJT) For P and DD packages, θJT = 3.0 OC / W. 3. If power consumption is over above rating, adequate heat sink is required to dissipate heat. RECOMMENDED OPERATING CONDITIONS Parameter Symbol Recommended Operating Conditions Units Min. Typ. Max. VPOWER 2 7 V 2.75 12 VCONTROL IO 0.010 10 33 7 A µF µF Input Voltage (VIN) Load Current (with adequate heatsinking) Input Capacitor (VIN to GND) Output Capacitor with ESR of 10Ω max., (VOUT to GND) Copyright © 2002, ADD Microtech Corp. 3 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 BLOCK DIAGRAM VPOW ER AMC7580 7A LOW DROPOUT REGULATOR VOUT VCONTROL SENSE THERMAL LIMIT 1.25V VREF Gnd AMC7580-X.X circuit schematic VCONTROL VPOW ER 1.25V VREF THERMAL LIMIT SENSE VOUT ADJ AMC7580-ADJ circuit schematic Copyright © 2002, ADD Microtech Corp. 4 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR ELECTRICAL CHARACTERISTICS Unless otherwise specified, these specifications apply TJ = 25°C for AMC7580; IO = 10mA, VOUT = VSENSE, and are for DC characteristics only. (Low duty cycle pulse testing techniques are used which maintains junction and case temperatures equal to the ambient temperature.) Parameter AMC7580-2.5 Output Voltage AMC7580-3.3 AMC7580-5.0 AMC7580-2.5 Output Voltage AMC7580-3.3 AMC7580-5.0 VOUT VOUT Symbol Test Conditions VCONTROL = 5.0V, VPOWER = 3.3V VCONTROL = 5.8V, VPOWER = 3.8V VCONTROL = 7.5V, VPOWER = 5.5V VCONTROL = 5.0V, VPOWER = 3.3V VCONTROL = 5.0V, VPOWER = 4.1V IO = 7A Min. 2.474 3.267 4.950 2.460 3.247 4.920 1.238 1.230 AMC7580 Typ. Max. 2.500 3.300 5.000 2.500 3.300 5.000 1.250 1.250 0.04 0.08 1.00 1.15 0.10 0.45 50 80 7 60 8 5 80 0.003 2.525 3.333 5.050 2.540 3.353 5.080 1.262 V 1.270 0.2 0.3 1.15 1.30 0.17 0.50 120 135 % % V V µA mA A mA dB %/W V V Units Reference Voltage AMC7580-ADJ VREF Line Regulation (Note 2) Load regulation (Note 2) Dropout Voltage VCONTROL - VOUT (Note 3) Dropout Voltage VPOWER- VOUT (Note 3) Adjust Pin Current Control Pin Current Current Limit Minimum Load Current (Note 4) Ripple Rejection (Note 5) Thermal Regulation VOI VOL V V IADJ ICTNL ICL Imin RR VCONTROL = 6.5V, VPOWER = 5.8V VCONTROL = 5.0V, VPOWER = 3.3V, (Note 1) VCONTROL = (VOUT + 1.5V) to 12V, VPOWER = (VOUT + 0.8V) to 7V, IO = 10mA to 7A (1.5V + VOUT) ≤ VCONTROL ≤ 12V, 0.8V ≤ (VPOWER - VOUT ) ≤ 5.5V VCONTROL = VOUT + 2.5V, VPOWER = VOUT + 0.8V, IO = 10mA to 7A IO = 10mA VPOWER = VOUT + 0.8V IO = 7A IO = 10mA VCONTROL = VOUT + 2.5V IO = 7A VCONTROL = 2.75V, VPOWER = 2.05V, IO = 10mA VCONTROL = VOUT + 2.5V, VPOWER = VOUT + 0.8V, IO = 10mA to 7A (VIN - VOUT)=1.5V VCONTROL = 5.0V, VPOWER = 3.3V VCONTROL = VPOWER = VOUT + 2.5V, VRIPPLE = 1VPP, IO = 2.5A TA = 25°C 10 Note 1 Output voltage is set to be 2.5V. Note 2: Line and load regulations are guaranteed up to maximum power dissipation determined by input/output differential and the output current. However, the maximum power will not be available over the full input/output voltage range. Note 3: The dropout voltage is measured by either minimum control voltage or power voltage. The specifications represent the minimum input/output voltage required to maintain 1% regulation. Note 4: The minimum load current is the minimum current required to maintain regulation. Normally the current in the resistor divider used to set the output voltage is selected to meet the minimum load current requirement. Note 5: These parameters, although guaranteed, are not tested in production prior to shipment Copyright © 2002, ADD Microtech Corp. 5 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR APPLICATION INFORMATION General The AMC7580 series is designed to power the new generation of microprocessors. It is designed to make use of multiple power supplies, present in most systems, to reduce the dropout voltage. One of the advantages of the twosupply approach is maximizing the efficiency. The second supply is at least 1V greater than output voltage and is providing the power for the control circuitry and supplies the drive current to the NPN output transistor. This allows the NPN output transistor to be driven into saturation. For the control voltage the current requirement is small, about 1% of the output current or approximately 50 mA for a 7A load. This drive current becomes part of the output current. The maximum voltage on the Control pin is 13 V. The maximum voltage at the Power pin is 7 V. By trying the control and power inputs together the AMC7580 can also be operated as a single supply device. In single supply operation, the dropout voltage will be determined by the minimum the Control voltage. The new generation of microprocessors cycle load current from several hundred milliamperes to several amperes in tens of nanoseconds. Output voltage tolerances are tighter and include transient response as part of the specification. Designed to meet the fast current load step requirements of these microprocessors, the AMC7580-X.X also saves total cost by needing less output capacitance to maintain regulation. The sense pin permits very accurate regulation of output voltage. As a result, over an output current range of 100mA to 7A, the typical load regulation is less than 1mV. In addition to the enhancements mentioned, the reference accuracy has been improved a factor of two with a guaranteed initial tolerance of ±1% at 25°C and 1.6% accuracy over the full temperature and load current range. Typical applications for the AMC7580 include 3.3V to 2.5 V conversion with a 5V control supply, 5V to 4.2V conversion with a 12V control supply or 5V to 3.6V conversion with a 12V control supply. It is easy to obtain dropout voltages of less than 0.5V at 2.5A along with excellent static and dynamic specifications. The device is fully protected against over current and over temperature conditions. Grounding and Output Sensing The AMC7580-ADJ allows true Kelvin sensing for both the high and low side of the load. As a result the voltage regulation at the load can be easily optimized. Voltage drops due to parasitic resistances between the regulator and the load can be placed inside the regulation loop. The advantages of remote sensing are illustrated in figures 1 through 3. Figure 1 shows the device connected as a conventional 3 terminal regulator with the Sense lead connected directly to the output of the device. Rp is the parasitic resistance of the connections between the device and the load. Trace A of figure 3 illustrates the effect of Rp. Figure 2 shows the device connected to take advantage of the remote sense feature. The Sense pin and the top of the resistor divider are connected to the top of the load; the bottom of the resistor divider is connected to the bottom of the load. The effect on output regulation can be seen in trace B of figure 3. It is important to note that the voltage drops due to Rp are not eliminated; they will add to the dropout voltage of the regulator regardless. TheAMC7580-ADJ can control the voltage at the load as long as the input-output voltage is greater than the total of the dropout voltage of the device plus the voltage drop across Rp. Copyright © 2002, ADD Microtech Corp. 6 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR Control Power Sense VOUT RP Control Power Sense VOUT ADJ ADJ RP R1 LOAD RP R1 R2 RP LOAD R2 Figure 1. Conventional Load Sensing Figure 2. Remote Load Sensing (∆IOUT)(RP) VOUT Figure 1 A VOUT Figure 2 B IOUT TIME Figure 3. Remote Sensing Improves Load Regulation Stability The Circuit design used in the AMC7580 series requires the use of an output capacitor as part of the device frequency compensation. The addition of 150µF Aluminum electrolytic or a 22µF solid tantalum on the output will ensure stability for all operating conditions. In order to meet the transient performance of the processor larger value capacitors are needed. To limit the high frequency noise generated by the processor, high quality bypass capacitors must be used. In order to limit parasitic inductance (ESL) and resistance (ESR) in capacitors to acceptable limits, multiple small ceramic capacitor in addition to high quality solid tantalum capacitors are required. When the adjustment terminal is bypassed to improve the ripple rejection, the requirement for an output capacitor increases. To further improve stability and transient response of these devices larger values of output capacitor can be used. The modern processors generate large high frequency current transients. The load current step contains higher order frequency components than the output coupling network must handle until the regulator throttles to the load current level. Because they contain parasitic resistance and inductance, capacitors are not ideal elements. These parasitic elements dominate the change in output voltage at the beginning of a transient load step change. The ESR of the output capacitors produces and instantaneous step in output voltage at the beginning of a transient load step change. The ESR of the output capacitors produces an instantaneous step in out voltage ∆V = ∆I(ESR). The ESL of the output capacitors produces a droop proportional to the rate of change of the output current ∆V = L(∆I/∆t). The output capacitance produces a change in output voltage proportional to the time until the regulator can respond ∆V = ∆t(∆I/C). Figure 4 illustrates these transient effects. Copyright © 2002, ADD Microtech Corp. 7 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR ESR Effects ESL Effects Capacitance Effects Slope, V/t = ∆I/C Point at which regulator takes control Figure 4. Output Voltage The AMC7580-ADJ develops a 1.25V reference voltage between the Sense pin and the Adjust pin (Figure 5). Placing a resistor between these two terminals causes a constant current to flow thought R1 and down though R2 to set the output voltage. In general R1 is chosen so that this current is the specified minimum load current of 10 mA. The current out of the Adjust pin is small, typically 50µA and it adds to the current for R1. For best regulation the top of the resistor divider should be connected directly to the Sense pin. VCONTROL VOUT VPOW ER AMC7580 -ADJ ADJ VREF SENSE R1 VCONTROL VPOW ER D1 D2 AMC7580 -ADJ ADJ SENSE R1 IADJ = 50µA R2 R2 Figure 5 Setting Output Voltage Figure 6. Optional Clamp Diodes Protect Against Input Crowbar Circuit Copyright © 2002, ADD Microtech Corp. 8 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR Protection Diodes In normal operation, AMC7580 family does not need any protection diodes between the adjustment pin and the output and from the output to the input to prevent die overstress. Internal resistors are limiting the internal current paths on the ADJ pin. Therefore even with bypass capacitors on the adjust pin no protection diode is needed to ensure device safety under short-circuit conditions. The Adjust pin can be driver on a transient basis ±7V with respect to the output without any device degradation. A protection diode between the Output pin and VPOWER pin is not usually needed. Microsecond surge currents of 50A to 100A can be handled by the internal diode between the Output pin and VPOWER pin of the device. In normal operations it is difficult to get those values of surge currents even with the use of large output capacitances. Only with high value output capacitors, such as 1000µF to 5000µF and the VPOWER pin is instantaneously shorted to ground, damage an occur. A diode from output to input is recommended (Figure 6). If AMC7851 is connected as single supply device with the control and power input pins shorted together the internal diode between the output and power input pin will protect the control input pin. Thermal Consideration The AMC7580-ADJ series has internal power and thermal limiting circuitry designed to protect the device under overload conditions. However maximum junction temperature ratings should not be exceeded under continuous normal load conditions. Careful consideration must be given to all sources of thermal resistance from junction to ambient, including junction-to-case, case-to-heat sink interface and heat sink resistance itself. Junction temperature of the Control section can run up to 125 OC. Junction temperature of the Power section can run up to 150 OC. Due to the thermal gradients between the power transistor and the control circuitry there is a significant difference in thermal resistance between the Control and Power sections. Virtually all the power dissipated by the device is dissipated in the power transistor. The temperature rise in the power transistor will be greater than the temperature rise in the Control section making the thermal resistance lower in the Control section. At power levels below 12W, the temperature gradient will be less than 25 OC and the maximum ambient temperature will be determined by the junction temperature of the Control section. This is due to the lower maximum junction temperature in the Control section. At power levels above 12W, the temperature gradient will be greater than 25 OC and the maximum ambient temperature will be determined by the Power section. In both cases the junction temperature is determined by the total power dissipated in the device. For most low dropout applications the power dissipation will be less than 12W. The power in the device is made up of two components: the power in the output transistor and the power in the control circuit. The power in the control circuit is negligible, which is equal to: PCONTROL = (VCONTROL – VOUT) / ICONTROL, where ICONTROL is equal IOUT / 100(typ) The power in the output transistor is equal to: POUTPUT = (VPOWER –VOUT) / IOUT The total power is equal to: PCONTROL + POUTPUT Junction-to-case thermal resistance is specified from the IC junction to the bottom of the case directly below the die. This is the lowest resistance path for the heat flow. In order to ensure the best possible thermal flow this area of the package to the heat sink proper mounting is required. Thermal compound at the case-to-heat sink interface is recommended. A thermally conductive spacer can be used, if the case of the device must be electrically isolated, but its added contribution to thermal resistance has to be considered. Copyright © 2002, ADD Microtech Corp. 9 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR Maximum Power Calculation: TJ(MAX) – TA(MAX) θJA TJ(OC): Maximum recommended junction temperature TA(OC): Ambient temperature of the application θJA(OC/W): Junction-to-junction temperature thermal resistance of the package, and other heat dissipating materials. The maximum power dissipation of a single-output regulator : PD(MAX) = [(VIN(MAX) - VOUT(NOM))] × IOUT(NOM) + VIN(MAX) × IQ PD(MAX)= Where: VOUT(NOM) = the nominal output voltage IOUT(NOM) = the nominal output current, and IQ = the quiescent current the regulator consumes at IOUT(MAX) VIN(MAX) = the maximum input voltage Then θJA = (150 OC – TA) / PD Thermal consideration: When power consumption is over about 1.2W( at 70oC ambient temperature), additional heat sink is required to control the junction temperature below 125OC. The junction temperature is: Tj = P D (θJT + θCS + θSA ) + T A P D:Dissipated power. θJT:Thermal resistance from the junction to the mounting tab of the package. θCS:  T h ermal resistance through the interface between the IC and the surface on which it is mounted. (typically, θCS < 1.0 °C / W) θSA:Thermal resistance from the mounting surface to ambient (thermal resistance of the heat sink). If PC Board copper is going to be used as a heat sink, below table can be used to determine the appropriate size of copper foil required. For multi-layered PCB, these layers can also be used as a heat sink. They can be connected with several through hole vias. 59 PCB θSA (°C / W ) 2 PCB heat sink size (mm ) 500 45 1000 38 1500 33 2000 27 3000 24 4000 21 5000 Recommended figure of PCB area used as a heat sink. through hole vias (Top View) (Bottom View) Copyright © 2002, ADD Microtech Corp. 10 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR 5-Pin Plastic TO-220 S B C INCHES MIN A 0.560 0.380 TY P MAX MILLIMETERS MIN TY P MAX 16.51 10.66 4.82 0.89 4.06 1.14 14.73 0.650 14.23 0.420 0.190 0.035 0.160 0.045 9.66 3.56 0.46 3.56 3.40 0.31 T F A B C 0.140 D 0.018 F 0.140 G 0.134 J K N K 0.012 0.500 0.580 12.70 0.268 TYP 0.115 0.055 0.270 2.04 1.14 5.85 6.80 TYP 2.92 1.39 6.85 R 0.080 S T 0.045 0.230 D G N R J 5-Pin Plastic TO-263 A I C D INCHES MIN A B 0.400 0.351 TY P MAX MILLIMETERS MIN TY P MAX 10.67 9.17 4.59 1.40 0.432 0.889 1.83 1.65 15.87 2.79 7° 3° 0.420 10.16 0.361 0.181 0.055 8.92 4.34 1.14 C 0.171 B K N M D 0.045 E F 0.013 0.029 0.017 0.330 0.035 0.737 0.072 0.065 1.57 - G 0.062 I L 0.575 0.090 K L 0.625 14.60 0.110 7° 3° 2.29 F G E M N Copyright © 2002, ADD Microtech Corp. 11 www.addmtek.com AMC DOC. #: AMC7580_E (LF) Feb 2005 AMC7580 7A LOW DROPOUT REGULATOR IMPORTANT NOTICE ADD Microtech (ADDM) reserves the right to make changes to its products or to discontinue any integrated circuit product or service without notice, and advises its customers to obtain the latest version of relevant information to verify, before placing orders, that the information being relied on is current. A few applications using integrated circuit products may involve potential risks of death, personal injury, or severe property or environmental damage. ADDM integrated circuit products are not designed, intended, authorized, or warranted to be suitable for use in life-support applications, devices or systems or other critical applications. Use of ADDM products in such applications is understood to be fully at the risk of the customer. In order to minimize risks associated with the customer’s applications, the customer should provide adequate design and operating safeguards. ADDM assumes to no liability to customer product design or application support. ADDM warrants the performance of its products to the specifications applicable at the time of sale. U.S. ADD Microtech Inc. 492 Altamont Drive Milpitas, CA 95035 T E L : (408) 9410420 F A X : (408) 9410864 Asia Pacific region ADD Microtech Corp 13F, NO. 287, Sec. 3, Nan Jing E. Rd., Taipei, Taiwan 105 T E L : 2-27132800 F A X : 2-27132805 Copyright © 2002, ADD Microtech Corp. 12 www.addmtek.com