US3007 5 BIT PROGRAMMABLE SYNCHRONOUS BUCK PLUS NON SYNCHRONOUS , LDO CONTROLLER AND 200MmA LDO ON BOARD PRELIMINARY DATASHEET FEATURES DESCRIPTION Provides Single Chip Solution for Vcore, GTL+ ,Clock Supply & 3.3V Switcher on board Second Switcher Provides Simple Control for the On board 3.3V supply 200 mA On board LDO regulator Designed to meet Intel VRM 8.2 and 8.3 specification for Pentium II On board DAC programs the output voltage from 1.3V to 3.5V Linear regulator controller on board for 1.5V GTL+ supply Loss less Short Circuit Protection Synchronous operation allows maximum efficiency Patented architecture allows fixed frequency operation as well as 100% duty cycle during dynamic load Minimum part count Soft Start High current totem pole driver for direct driving of the external Power MOSFET Power Good function Monitors all Outputs OVP Circuitry Protects the Switcher Outputs and generates a Fault output Thermal Shutdown APPLICATIONS Total Power Soloution for Pentium II processor application The US3007 controller IC is specifically designed to meet Intel specification for Pentium II microprocessor applications as well as the next generation of P6 family processors. The US3007 provides a single chip controller IC for the Vcore , LDO controller for GTL+ and an internal 200mA regulator for clock supply which are required for the Pentium II applications. It also contains a switching controller to convert 5V to 3.3V regulator for an on board applications that either uses AT type power supply or it is desired not to rely on the ATX power supply’s 3.3V output. These devices feature a patented topology that in combination with a few external components as shown in the typical application circuit ,will provide in excess of 14A of output current for an on- board DC/DC converter while automatically providing the right output voltage via the 5 bit internal DAC .The US3007 also features, loss less current sensing for both switchers by using the Rds-on of the high side Power MOSFET as the sensing resistor, internal current limiting for the clock supply, a Power Good window comparator that switches its open collector output low when any one of the outputs is outside of a pre programmed window. Other features of the device are ; Undervoltage lockout for both 5V and 12V supplies, an external programmable soft start function , programming the oscillator frequency via an external resistor, OVP circuitry for both switcher outputs and an internal thermal shutdown. TYPICAL APPLICATION 5V SWITCHER2 CONTROL Vout2 SWITCHER1 CONTROL Vout1 LINEAR REGULATOR Vout4 US3007 LINEAR CONTROL Vout3 3007app3-1.0 Notes: Pentium II and Pentium Pro are trade marks of Intel Corp. PACKAGE ORDER INFORMATION Ta (°C) 0 TO 70 Rev. 1.8 12/8/00 Device US3007CW Package 28 pin Plastic SOIC WB 4-1 US3007 ABSOLUTE MAXIMUM RATINGS V5 supply Voltage ........................................... 7V V12 Supply Voltage ............................................ 20V Storage Temperature Range ................................. -65 TO 150°C Operating Junction Temperature Range .......... 0 TO 125°C PACKAGE INFORMATION 28 PIN WIDE BODY PLASTIC SOIC (W) TOP VIEW UGate2 1 28 V12 Phase2 2 27 UGate1 VID4 3 26 Phase1 VID3 4 25 LGate1 VID2 5 24 PGnd VID1 6 23 OCSet1 VID0 7 22 Vsen1 PGood 8 21 Fb1 OCSet2 9 20 NC Fb2 10 19 Fb3 V5 11 18 Gate3 SS 12 17 Gnd Fault / Rt 13 16 Vout4 Fb4 14 15 Vsen2 θJA =80°C/W ELECTRICAL SPECIFICATIONS Unless otherwise specified ,these specifications apply over ,V12 = 12V, V5 = 5V and Ta=0 to 70°C. Typical values refer to Ta =25°C. Low duty cycle pulse testing are used which keeps junction and case temperatures equal to the ambient temperature. PARAMETER SYM TEST CONDITION MIN TYP MAX UNITS Supply UVLO Section UVLO Threshold-12V Supply ramping up 10 V UVLO Hysterises-12V 0.4 V UVLO Threshold-5V Supply ramping up 4.3 V UVLO Hysterises-5V 0.3 V Supply Current Operating Supply Current V12 6 mA V5 30 Switching Controllers; Vcore (Vout 1) and I/O (Vout 2) VID Section (Vcore only) DAC output voltage (note 1) 0.99Vs Vs 1.01Vs V DAC Output Line Regulation 0.1 % DAC Output Temp Variation 0.5 % VID Input LO 0.8 V VID Input HI 2 V VID input internal pull-up resistor to V5 27 kΩ Vfb2 Voltage 2 V 4-2 Rev. 1.8 12/8/00 US3007 Error Comparator Section Input bias current Input Offset Voltage Delay to Output Current Limit Section C.S Threshold Set Current C.S Comp Offset Voltage Hiccup Duty Cycle Output Drivers Section Rise Time Fall Time Dead band Time Between High side and Synch Drive (Vcore Switcher Only) Oscillator Section (internal) Osc Frequency 2.5V Regulator (Vout 4) Reference Voltage Vo4 Reference Voltage Dropout Voltage Load Regulation Line Regulation Input bias current Output Current Current limit Thermal Shutdown 1.5V Regulator (Vout 3) Reference Voltage Vo3 Reference Voltage Input bias current Output Drive Current Power Good Section Core U.V lower trip point Core U.V upper trip point Core U.V Hysterises Core O.V upper trip point Core O.V lower trip point Core O.V Hysterises I/O U.V lower trip point I/O U.V upper trip point FB4 lower trip point FB4 upper trip point FB3 lower trip point FB3 upper trip point Power Good Output LO Power Good Output HI Fault (Overvoltage) Section Core O.V. upper trip point Core O.V. lower trip point Soft Start Section Pull up resistor to 5V Rev. 1.8 12/8/00 -2 Vdiff=10mV 2 +2 100 uA mV nS +5 200 Css=0.1 uF 10 uA mV % CL=3000pF CL=3000pF 70 70 nS nS CL=3000pF 200 nS Rt=Open 200 Khz Ta=25, Vout4 = FB4 1.260 1.260 0.6 0.5 0.2 V V V % % uA mA mA °C -5 Io = 200 mA 1mA< Io <200 mA 3.1V<VIO<4V, Vo=2.5V 2 200 300 145 Ta=25, GATE3 = FB3 1.260 1.260 2 50 Vsen1 ramping down Vsen1 ramping up V V uA mA Vsen2 ramping down Vsen2 ramping up FB4 ramping down FB4 ramping up FB3 ramping down FB3 ramping up RL=3mA RL=5K pull up to 5V 0.90Vs 0.92Vs .02Vs 1.10Vs 1.08Vs .02Vs 2.4 2.6 0.95 1.05 0.95 1.05 0.4 4.8 V V V V V V V V V V V V V V Vsen1 ramping up Vsen1 ramping down 1.17Vs 1.15Vs V V OCset=0V , Phase=5V 23 KΩ Vsen1 ramping up Vsen1 ramping down 4-3 US3007 I/O O.V. upper trip point Vsen2 ramping up I/O O.V. lower trip point Vsen2 ramping down FAULT Output HI Io=3mA Note 1: Vs refers to the set point voltage given in Table 1. D4 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 D3 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 D2 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 D1 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 D0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 Vs 1.30 1.35 1.40 1.45 1.50 1.55 1.60 1.65 1.70 1.75 1.80 1.85 1.90 1.95 2.00 2.05 D4 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 4.3 4.2 10 D3 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 D2 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 V V V D1 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 D0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 Vs 2.0 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 Table 1 - Set point voltage vs. VID codes PIN DESCRIPTIONS PIN# PIN SYMBOL 7 VID0 6 VID1 5 VID2 4 VID3 3 VID4 8 PGOOD 21 FB1 4-4 Pin Description LSB input to the DAC that programs the output voltage. This pin is TTL compatible that realizes a logic “1” as either HI or Open. When left open,his pin is pulled up internally by a 27kΩ resistor to 5V supply. Input to the DAC that programs the output voltage. This pin is TTL compatible that realizes a logic “1” as either HI or Open. When left open,his pin is pulled up internally by a 27kΩ resistor to 5V supply. Input to the DAC that programs the output voltage. This pin is TTL compatible that realizes a logic “1” as either HI or Open. When left open,his pin is pulled up internally by a 27kΩ resistor to 5V supply. MSB input to the DAC that programs the output voltage. This pin is TTL compatible that realizes a logic “1” as either HI or Open. When left open,his pin is pulled up internally by a 27kΩ resistor to 5V supply. This pin selects a range of output voltages for the DAC.When in the LOW state the range is 1.3V to 2.05V and when it switches to HI state the range is 2.0V to 3.5V. This pin is TTL compatible that realizes a logic “1” as either HI or Open. When left open,his pin is pulled up internally by a 27kΩ resistor to 5V supply. This pin is an open collector output that switches LO when any of the outputs are outside of the specified under voltage trip point. It also switches low when Vsen1 pin is more than 10% above the DAC voltage setting. This pin provides the feedback for the synchronous switching regulator. Typically this pin can be connected directly to the output of the switching regulator. However, a resistor divider is recommended to be connected from this pin to vout1 and GND to adjust the output voltage for any drop in the output voltage that is caused by the trace resistance. The value of the resistor connected from Vou1 to FB1 must be less than 100Ω. Rev. 1.8 12/8/00 US3007 PIN# PIN SYMBOL Pin Description 22 VSEN1 10 FB2 15 VSEN2 23 OCSET1 26 PHASE1 9 OCSET2 2 PHASE2 12 SS 13 FAULT/Rt 18 19 16 14 17 24 GATE3 FB3 VOUT4 FB4 GND PGND 25 27 1 28 LGATE1 UGATE1 UGATE2 V12 11 V5 20 N.C This pin is internally connected to the undervoltage and overvoltage comparators sensing the Vcore status. It must be connected directly to the Vcore supply. This pin provides the feedback for the non-synchronous switching regulator. A resistor divider is connected from this pin to vout2 and GND that sets the output voltage. The value of the resistor connected from Vout2 to FB2 must be less than 100Ω. This pin is connected to the output of the I/O switching regulator. It is an input that provides sensing for the Under/Over voltage circuitry for the I/O supply as well as the power for the internal LDO regulator. This pin is connected to the Drain of the power MOSFET of the Core supply and it provides the positive sensing for the internal current sensing circuitry. An external resistor programs the C.S threshold depending on the Rds of the power MOSFET. An external capacitor is placed in parallel with the programming resistor to provide high frequency noise filtering. This pin is connected to the Source of the power MOSFET for the Core supply and it provides the negative sensing for the internal current sensing circuitry. This pin is connected to the Drain of the power MOSFET of the I/O supply and it provides the positive sensing for the internal current sensing circuitry. An external resistor programs the C.S threshold depending on the Rds of the power MOSFET. An external capacitor is placed in parallel with the programming resistor to provide high frequency noise filtering. This pin is connected to the Source of the power MOSFET for the I/O supply and it provides the negative sensing for the internal current sensing circuitry. This pin provides the soft start for the 2 switching regulators. An internal resistor charges an external capacitor that is connected from 5V supply to this pin which ramps up the outputs of the switching regulators, preventing the outputs from overshooting as well as limiting the input current. The second function of the Soft Start cap is to provide long off time (HICCUP) for the synchronous MOSFET during current limiting. This pin has dual function. It acts as an output of the OVP circuitry or it can be used to program the frequency using an external resistor . When used as a fault detector, if any of the switcher outputs exceed the OVP trip point, the FAULT pin switches to 12V and the soft start cap is discharged. If the FAULT pin is to be connected to any external circuitry, it needs to be buffered as shown in the application circuit. This pin controls the gate of an external transistor for the 1.5V GTL+ linear regulator. This pin provides the feedback for the linear regulator that its output drive is GATE3. This pin is the output of the internal LDO regulator. This pin provides the feedback for the internal LDO regulator that its output is Vout4. This pin serves as the ground pin and must be connected directly to the ground plane. This pin serves as the Power ground pin and must be connected directly to the GND plane close to the source of the synchronous MOSFET. A high frequency capacitor (typically 1 uF) must be connected from V12 pin to this pin for noise free operation. Output driver for the synchronous power MOSFET for the Core supply. Output driver for the high side power MOSFET for the Core supply. Output driver for the high side power MOSFET for the I/O supply. This pin is connected to the 12 V supply and serves as the power Vcc pin for the output drivers. A high frequency capacitor (typically 1 uF) must be placed close to this pin and PGND pin and be connected directly from this pin to the GND plane for the noise free operation. 5V supply voltage. A high frequency capacitor (0.1 to 1 uF) must be placed close to this pin and connected from this pin to the GND plane for noise free operation. No connect Rev. 1.8 12/8/00 4-5 US3007 BLOCK DIAGRAM 4.3V Enable V12 Over Voltage 28 UVLO V5 11 Vset Enable 1.17Vset Vset 7 VID1 6 VID2 5 VID3 4 VID4 3 Vsen1 22 Fb3 19 Gate3 18 Vsen2 15 1.1Vset Enable 16 14 PGood 8 25 LGate1 26 Phase1 Osc Soft Start & Fault Logic Over Current 0.9Vset 23 OCSet1 2 Phase2 9 OCSet2 13 Fault / Rt 1 UGate2 24 PGnd 17 Gnd 10 Fb2 12 SS V12 Slope Comp 1.26V 0.9V PWM Control + V5 2.0V Fb4 UGate1 200uA V12 Vout4 27 V12 Slope Comp 2.5V 5Bit DAC Fb1 PWM Control + VID0 21 V12 Enable 3007blk1-1.4 Figure 1 - Simplified block diagram of the US3007 4-6 Rev. 1.8 12/8/00 TYPICAL APPLICATION R22 12V L1 C5 5V C2 R9 C8 R12 C10 C14 C3 9 OCSet2 R10 Q1 28 V12 23 OCSet1 1 UGate2 UGate1 27 2 Phase2 Phase1 26 R13 Q3 L3 L2 Vout2 3.0V - 3.5V C1 Vout1 1.8V - 3.5V C16 R14 C4 Q4 LGate1 25 D1 R1 C13 R15 15 Vsen2 Vsen1 22 10 Fb2 R2 Fb1 21 R17 U1 R3 5V R16 R21 PGnd 24 R19 11 V5 C15 NC 20 C19 PGood 8 Q2 18 Gate3 PGood Fault/Rt 13 R5 19 Fb3 Vout3 1.5V C17 VID0 7 VID1 6 R6 VID2 5 VID3 4 16 Vout4 Vout4 2.5V C18 Fb4 14 R7 VID4 3 Gnd 17 SS 12 3007app1-1.2 R8 5V C9 Figure 2 - Typical application of US3007 for an on board DC-DC converter providing power for the Vcore , GTL+, Clock supply as well as an on board 3.3V I/O supply for the Deschutes and the next generation processor applications. Rev. 1.8 12/8/00 4-7 US3007 US3007 Application Parts List Ref Desig Q1 Q2 Q3 Q4 D1 L1 Description MOSFET MOSFET MOSFET MOSFET with Schottky Diode Inductor L2 Inductor Qty 1 1 1 1 1 1 1 1 L3 Inductor 1 C1 C2 C3 C4,13 C5,10 C8 C9,15,19 C14 C16 C17 C18 R1,5,13 ,14 R2 R3,6,7,8 R5 R9 R10 R12 R16,17,21 R19 R22 Capacitor, Electrolytic Capacitor, Electrolytic Capacitor, Electrolytic Capacitor, Ceramic Capacitor, Ceramic Capacitor, Ceramic Capacitor, Ceramic Capacitor, Electrolytic Capacitor, Electrolytic Capacitor, Electrolytic Capacitor, Electrolytic Resistor 2 1 1 2 2 1 3 2 6 1 1 4 Part # IRL3103S, TO263 package RLR024, TO252 package IRL3103S, TO263 package IRL3103D1S, TO263 package MBRB1035, TO263 package L=1uH, 5052 core with 4 turns of 1.0mm wire L=4.7uH, 5052 core with 11 turns of 1.0mm wire L=2.7uH, 5052B core with 7 turns of 1.2mm wire 6MV1500GX, 1500uF,6.3V 10MV470GX, 470uF,10V 10MV1200GX, 1200uF,10V 1000pF, 0603 220pF, 0603 1uF, 0805 1uF, 0603 10MV1200GX, 1200uF,10V 6MV1500GX, 1500uF,6.3V 6MV1000GX, 1000uF,6.3V 6MV150GX, 150uF,6.3V 4.7Ω, 5%, 1206 Resistor Resistor Resistor Resistor Resistor Resistor Resistor Resistor Resistor 1 4 1 1 1 1 3 1 1 75Ω, 1%, 0603 100Ω, 1%, 0603 19.1Ω, 1%, 0603 1.5kΩ, 5%, 0603 10Ω, 5%, 1206 3.3kΩ, 5%, 0603 2.2kΩ, 1%, 0603 220kΩ, 1%, 0603 10Ω, 5%, 0603 4-8 Manufacture IR IR IR IR IR Micro Metal Micro Metal Micro Metal Sanyo Sanyo Sanyo Sanyo Sanyo Sanyo Sanyo Rev. 1.8 12/8/00 US3007 TYPICAL APPLICATION (Dual Layout with HIP6019) R22 12V L1 C5 5V C2 R9 C8 R12 C10 C14 C3 9 OCSet2 R10 Q1 28 V12 23 OCSet1 1 UGate2 UGate1 27 2 Phase2 Phase1 26 R13 Q3 L3 L2 Vout2 3.0V - 3.5V C1 Vout1 1.8V - 3.5V C16 R14 C4 Q4 LGate1 25 D1 R1 C13 R15 PGnd 24 15 Vsen2 Vsen1 22 10 Fb2 R2 Fb1 21 U1 R11 11 V5/Comp2 R4 C15 NC/Comp1 20 C11 C19 C7 Q2 R17 C12 C6 R3 R16 R21 R18 R19 PGood PGood 8 18 Gate3 Fault/Rt 13 R5 Vout3 1.5V 19 Fb3 C17 VID0 7 VID1 6 R6 VID2 5 VID3 4 Vout4 2.5V 16 Vout4 C18 Fb4 14 R7 VID4 3 Gnd 17 SS 12 3007app2-1.5 R8 5V C20 C9 Figure 3 - Typical application of US3007 in a dual layout with HIP6019 for an on board DC-DC converter providing power for the Vcore , GTL+, Clock supply as well as an on board 3.3V I/O supply for the Deschutes and the next generation processor applications. Components that need to be modified to make the dual layout work for US3007 and HIP6019. Part # R4 R11 HIP6019 V O US3007 O S S - Short O - Open R18 C6 C7 C9 C11 C12 V V V O V V O O O V O O V - See Unisem or Harris parts list for the value. C19 O V C20 V O Table 2 - Dual layout component table Rev. 1.8 12/8/00 4-9 US3007 US3007 Application Parts List Dual Layout with HIP6019 Ref Desig Q1 Q2 Q3 Q4 D1 L1 Description MOSFET MOSFET MOSFET MOSFET with Schottky Diode Inductor Qty 1 1 1 1 1 1 L2 Inductor 1 L3 Inductor 1 C1 C2 C3 C4,13 C5,10 C6,7,11,12 ,20 C8 C9,15,19 C14 C16 C17 C18 R1,13,14 ,15 R2 R3,6,7,8 R4,18 Capacitor, Electrolytic Capacitor, Electrolytic Capacitor, Electrolytic Capacitor, Ceramic Capacitor, Ceramic Capacitor, Ceramic 2 1 1 2 2 5 Capacitor, Ceramic Capacitor, Ceramic Capacitor, Electrolytic Capacitor, Electrolytic Capacitor, Electrolytic Capacitor, Electrolytic Resistor 1 3 2 6 1 1 4 Resistor Resistor Resistor 1 4 2 R5 R9 R10 R11 R12 R16,17,21 R19 R22 Resistor Resistor Resistor Resistor Resistor Resistor Resistor Resistor 1 1 1 1 1 3 1 1 4-10 Part # IRL3103S, TO263 package IRLR024, TO252 package IRL3103S, TO263 package IRL3103D1S, TO263 package MBRB1035, TO263 package L=1uH, 5052 core with 4 turns of 1.0 mm wire L=4.7uH, 5052 core with 11 turns of 1.0mm wire L=2.7uH, 5052B core with 7 turns of 1.2mm wire 6MV1500GX, 1500uF,6.3V 10MV470GX, 470uF,10V 10MV1200GX, 1200uF,10V 1000pF, 0603 220pF, 0603 See Table 2, dual layout component 0603 * 5 1uF, 0805 1uF, 0603 10MV1200GX, 1200uF,10V 6MV1500GX, 1500uF,6.3V 6MV1000GX, 1000uF,6.3V 6MV150GX, 150uF,6.3V 4.7Ω, 5%, 1206 Manuf IR IR IR IR IR Micro Metal Micro Metal Micro Metal Sanyo Sanyo Sanyo Sanyo Sanyo Sanyo Sanyo 75Ω, 1%, 0603 100Ω, 1%, 0603 See Table 2, dual layout component 0603 * 2 19.1Ω, 1%, 0603 1.5kΩ, 5%, 0603 10Ω, 5%, 1206 0Ω, 0603 3.3kΩ, 5%, 0603 2.2kΩ, 1%, 0603 220kΩ, 1%, 0603 10Ω, 5%, 0603 Rev. 1.8 12/8/00 US3007 Application Information An example of how to calculate the components for the application circuit is given below. Assuming, two set of output conditions that this regulator must meet for Vcore : a) Vo=2.8V , Io=14.2A, ∆Vo=185mV, ∆Io=14.2A b) Vo=2V , Io=14.2A, ∆Vo=140mV, ∆Io=14.2A Also, the on board 3.3V supply must be able to provide 10A load current and maintain less than ±5% total output voltage variation. The regulator design will be done such that it meets the worst case requirement of each condition. Output Capacitor Selection Vcore The first step is to select the output capacitor. This is done primarily by selecting the maximum ESR value that meets the transient voltage budget of the total ∆Vo specification. Assuming that the regulators DC initial accuracy plus the output ripple is 2% of the output voltage, then the maximum ESR of the output capacitor is calculated as : ESR ≤ 100 = 7 mΩ 14.2 The Sanyo MVGX series is a good choice to achieve both the price and performance goals. The 6MV1500GX , 1500uF, 6.3V has an ESR of less than 36 mΩ typ . Selecting 6 of these capacitors in parallel has an ESR of ≈6 mΩ which achieves our low ESR goal. Other type of Electrolytic capacitors from other manufacturers to consider are the Panasonic “FA” series or the Nichicon “PL” series. 3.3V supply For the 3.3V supply, since there is not fast transient requirement, 2 of the 1500uf capacitors is sufficient. Reducing the Output Capacitors Using Voltage Level Shifting Technique The trace resistance or an external resistor from the output of the switching regulator to the Slot 1 can be used to the circuit advantage and possibly reduce the number of output capacitors, by level shifting the DC regulation point when transitioninig from light load to full load and vice versa. To accomplish this, the output of the regulator is typically set about half the DC drop that results from light load to full load. For example, if the total resistance from the output capacitors to the Slot 1 and back to the GND pin of the 3007 is 5mΩ and Rev. 1.8 12/8/00 if the total ∆I, the change from light load to full load is 14A, then the output voltage measured at the top of the resistor divider which is also connected to the output capacitors in this case, must be set at half of the 70 mV or 35mV higher than the DAC voltage setting. This intentional voltage level shifting during the load transient eases the requirement for the output capacitor ESR at the cost of load regulation. One can show that the new ESR requirement eases up by half the total trace resistance. For example, if the ESR requirement of the output capacitors without voltage level shifting must be 7mΩ then after level shifting the new ESR will only need to be 8.5mΩ if the trace resistance is 5mΩ (7+5/2=9.5). However, one must be careful that the combined “voltage level shifting” and the transient response is still within the maximum tolerance of the Intel specification. To insure this, the maximum trace resistance must be less than: Rs≤ 2(Vspec - 0.02*Vo - ∆Vo)/∆I Where : Rs=Total maximum trace resistance allowed Vspec=Intel total voltage spec Vo=Output voltage ∆Vo=Output ripple voltage ∆I=load current step For example, assuming: Vspec=±140 mV=±0.1V for 2V output Vo=2V ∆Vo=assume 10mV=0.01V ∆I=14.2A Then the Rs is calculated to be: Rs≤ 2(0.140 - 0.02*2 - 0.01)/14.2=12.6mΩ However, if a resistor of this value is used, the maximum power dissipated in the trace (or if an external resistor is being used) must also be considered. For example if Rs=12.6 mΩ , the power dissipated is (Io^2)*Rs=(14.2^2)*12.6=2.54W. This is a lot of power to be dissipated in a system. So, if the Rs=5mΩ, then the power dissipated is about 1W which is much more acceptable. If level shifting is not implemented, then the maximum output capacitor ESR was shown previously to be 7mΩ which translated to ≈ 6 of the 1500uF, 6MV1500GX type Sanyo capacitors. With Rs=5mΩ, the maximum ESR becomes 9.5mΩ which is equivalent to ≈ 4 caps. Another important consideration is that if a trace is being used to implement the resistor, the power dissipated by the trace increases the case temperature of the output capacitors which could seriously effect the life time of the output capacitors. 4-11 US3007 Output Inductor Selection The output inductance must be selected such that under low line and the maximum output voltage condition, the inductor current slope times the output capacitor ESR is ramping up faster than the capacitor voltage is drooping during a load current step. However if the inductor is too small , the output ripple current and ripple voltage become too large. One solution to bring the ripple current down is to increase the switching frequency , however that will be at the cost of reduced efficiency and higher system cost. The following set of formulas are derived to achieve the optimum performance without many design iterations. The maximum output inductance is calculated using the following equation : L = ESR * C * ( Vinmin - Vomax ) / ( 2* ∆I ) Where : Vinmin = Minimum input voltage For Vo = 2.8 V , ∆I = 14.2 A L =0.006 * 9000 * ( 4.75 - 2.8) / (2 * 14.2) = 3.7 uH Assuming that the programmed switching frequency is set at 200 KHZ , an inductor is designed using the Micrometals’ powder iron core material. The summary of the design is outlined below : The selected core material is Powder Iron , the selected core is T50-52D from Micro Metal wounded with 8 Turns of # 16 AWG wire, resulting in 3 uH inductance with ≈ 3 mΩ of DC resistance. Assuming L = 3 uH and the switching frequency ; Fsw = 200 KHZ , the inductor ripple current and the output ripple voltage is calculated using the following set of equations : T = 1/Fsw T ≡ Switching Period D ≈ ( Vo + Vsync ) / ( Vin - Vsw + Vsync ) D ≡ Duty Cycle Ton = D * T Vsw ≡ High side Mosfet ON Voltage = Io * Rds Rds ≡ Mosfet On Resistance Toff = T - Ton Vsync ≡ Synchronous MOSFET ON Voltage=Io * Rds ∆Ir = ( Vo + Vsync ) * Toff /L ∆Ir ≡ Inductor Ripple Current ∆Vo = ∆Ir * ESR ∆Vo ≡Output Ripple Voltage 4-12 In our example for Vo = 2.8V and 14.2 A load , Assuming IRL3103 MOSFET for both switches with maximum on resistance of19 m Ω, we have : T = 1 / 200000 = 5 uSec Vsw =Vsync= 14.2*0.019=0.27 V D ≈ ( 2.8 + 0.27 ) / ( 5 - 0.27 + 0.27 ) = 0.61 Ton = 0.61 * 5 = 3.1 uSec Toff = 5 - 3.1 = 1.9 uSec ∆Ir = ( 2.8 + 0.27 ) * 1.9 / 3 = 1.94 A ∆Vo = 1.94 * .006 = .011 V = 11 mV Power Component Selection Vcore Assuming IRL3103 MOSFETs as power components, we will calculate the maximum power dissipation as follows: For high side switch the maximum power dissipation happens at maximum Vo and maximum duty cycle. Dmax ≈ ( 2.8 + 0.27 ) / ( 4.75 - 0.27 + 0.27 ) = 0.65 Pdh = Dmax * Io^2*Rds(max) Pdh= 0.65*14.2^2*0.029=3.8 W Rds(max)=Maximum Rds-on of the MOSFET at 125°C For synch MOSFET, maximum power dissipation happens at minimum Vo and minimum duty cycle. Dmin ≈ ( 2 + 0.27 ) / ( 5.25 - 0.27 + 0.27 ) = 0.43 Pds = (1-Dmin)*Io^2*Rds(max) Pds=(1 - 0.43) * 14.2^2 * 0.029 = 3.33 W 3.3V Supply Again,for high side switch the maximum power dissipation happens at maximum Vo and maximum duty cycle. The duty cycle equation for non synchronous replaces the forward voltage of the diode with the Synch MOSFET on voltage. In equation below, Vf=0.5V Dmax ≈ ( 3.3 + 0.5 ) / ( 4.75 - 0.27 + 0.5 ) = 0.76 Pdh = Dmax * Io^2*Rds(max) Pdh= 0.76*10^2*0.029=2.21 W Rds(max)=Maximum Rds-on of the MOSFET at 125°C For diode, the maximum power dissipation happens at minimum Vo and minimum duty cycle. Dmin ≈ ( 3.3 + 0.5 ) / ( 5.25 - 0.27 + 0.5 ) = 0.69 Pdd = (1-Dmin)*Io*Vf=(1 - 0.69) * 10 * 0.5 = 1.55 W Switcher Current Limit Protection The US3007 uses the MOSFET Rds-on as the sensing resistor to sense the MOSFET current and compares to a programmed voltage which is set externally via a resistor (Rcs) placed between the drain of the MOSFET and the “CS+” terminal of the IC as shown in the application circuit. Rev. 1.8 12/8/00 US3007 For example, if the desired current limit point is set to be 22A for the synchronous and 16A for the non synchronous , and from our previous selection, the maximum MOSFET Rds-on =19mW, then the current sense resistor Rcs is calculated as : Vcore Vcs=IcL*Rds=22*0.019=0.418V Rcs=Vcs/Ib=(0.418V)/(200uA)=2.1kΩ Where: Ib=200uA is the internal current setting of the US3007 3.3V supply Vcs=IcL*Rds=16*0.019=0.3V Rcs=Vcs/Ib=(0.3V)/(200uA)=1.50kΩ 1.5V, GTL+ Supply LDO Power MOSFET Selection The first step in selectiong the power MOSFET for the 1.5V linear regulator is to select its maximum Rds-on of the pass transistor based on the input to output Dropout voltage and the maximum load current. Rds(max)=(Vin - Vo)/IL For Vo=1.5V, and Vin=3.3V , IL=2A Rds-max=(3.3 - 1.5)/2= 0.9Ω Note that since the MOSFETs Rds-on increases with temperature, this number must be divided by ≈ 1.5, inorder to find the Rds-on max at room temperature. The Motorola MTP3055VL has a maximum of 0.18Ω Rds-on at room temperature, which meets our requirement. To select the heatsink for the LDO Mosfet the first step is to calculate the maximum power dissipation of the device and then follow the same procedure as for the switcher. Pd = ( Vin - Vo ) * IL Where : Pd = Power Dissipation of the Linear Regulator IL = Linear Regulator Load Current For the 1.5V and 2A load: Pd = (3.3 - 1.5)*2=3.6 W Assuming Tj-max=125°C Ts = Tj - Pd * (θjc + θcs) Ts = 125 - 3.6 * (1.8 + 0.05) = 118 °C With the maximum heat sink temperature calculated in the previous step, the Heat Sink to Air thermal resistance (θsa) is calculated as follows : Assuming Ta=35 °C ∆T = Ts - Ta = 118 - 35 = 83 °C Temperature Rise Above Ambient θsa = ∆T/Pd θsa = 83 / 3.6 = 23 °C/W Rev. 1.8 12/8/00 The same heat sink as the one selected for the switcher MOSFETs is also suitable for the 1.5V regulator. 2.5V, Clock Supply The US3007 provides a complete 2.5V regulator with a minimum of 200mA current capability. The internal regulator has short circuit protection with internal thermal shutdown. 1.5V and 2.5V Supply Resistor Divider Selection Since the internal voltage reference for the linear regulators is set at 1.26V for US3007, there is a need to use external resistor dividers to step up the voltage. The resistor dividers are selected using the following equations: Vo=(1+Rt/Rb)*Vref Where: Rt=Top resistor divider Rb=Bottom resistor divider Vref=1.26V typical For 1.5V supply : Assuming Rb=1kΩ Rt=Rb*[(Vo/Vref) - 1] Rt=1*[(1.5/1.26) - 1]=191Ω For 2.5V supply : Assuming Rb=1.02kΩ Rt=Rb*[(Vo/Vref) - 1] Rt=1.02*[(2.5/1.26) - 1]=1kΩ Switcher Output Voltage Adjust Vcore As it was discussed earlier,the trace resistance from the output of the switching regulator to the Slot 1 can be used to the circuit advantage and possibly reduce the number of output capacitors, by level shifting the DC regulation point when transitioninig from light load to full load and vice versa. To account for the DC drop, the output of the regulator is typically set about half the DC drop that results from light load to full load. For example, if the total resistance from the output capacitors to the Slot 1 and back to the GND pin of the 3007 is 5mΩ and if the total ∆I, the change from light load to full load is 14A, then the output voltage measured at the top of the resistor divider which is also connected to the output capacitors in this case, must be set at half of the 70 mV or 35mV higher than the DAC voltage setting. To do this, the top resistor of the resistor divider(R17 in the application circuit) is set at 100Ω, and the R19 is calculated. For example, if DAC voltage setting is for 2.8V and the desired output under light load is 2.835V, then R19 is calculated using the following formula : 4-13 US3007 R19= 100*{Vdac /(Vo - 1.004*Vdac)} [Ω] R19= 100*{2.8 /(2.835 - 1.004*2.800)} = 11.76 kΩ Select 11.8 kΩ , 1% Note: The value of the top resistor must not exceed 100Ω. The bottom resistor can then be adjusted to raise the output voltage. 3.3V supply The loop gain for the non synchronous switching regulator is intentionally set low to take advantage of the level shifting technique to reduce the number of output capacitors. Typically there is a 1% drop in the output voltage from light load (discontinous conduction mode) to full load (continous conduction mode) in the 3.3V supply. To account for this, the output voltage is set at 3.5V typically. The same procedure as for the synchronous is applied to the non synch with the exception that the internal voltage reference of this regulator is internally set at 2V. The following is the set of equations to use for the output voltage setting for the non-synchronous assuming the Vo=3.5V and the top resistor,( R2 in the application circuit ) is; R2=75Ω. The bottom resistor, R3 is calculated as follows: R3= R2*{2 /(Vo - 2)} [Ω] R3= 75*{2 /(3.5 - 2)} = 100Ω , 1% Note: The value of the top resistor , R2 must not exceed 100Ω. Soft Start Capacitor Selection The soft start capacitor must be selected such that during the start up when the output capacitors are charging up, the peak inductor current does not reach the current limit treshold. A minimum of 1uF capacitor insures this for most applications. An internal 10uA current source charges the soft start capacitor which slowly ramps up the inverting input of the PWM comparator Vfb3. This insures the output voltage to ramp at the same rate as the soft start cap thereby limiting the input current. For example, with 1uF and the 10uA internal current source the ramp up rate is (∆V/ ∆t)=I/C = 1V/100mS. Assuming that the output capacitance is 9000uF, the maximum start up current will be: I=9000uF*(1V/100mS)=0.09A Input Filter It is highly recommended to place an inductor between the system 5V supply and the input capacitors of the switching regulator to isolate the 5V supply from the switching noise that occurs during the turn on and off of the switching components. Typically an inductor in the range of 1 to 3 uH will be sufficient in this type of application. 4-14 External Shutdown The best way to shutdown the US3007 is to pull down on the soft start pin using an external small signal transistor such as 2N3904 or 2N7002 small signal MOSFET. This allows slow ramp up of the output, the same as the power up. Layout Considerations Switching regulators require careful attention to the layout of the components, specifically power components since they switch large currents. These switching components can create large amount of voltage spikes and high frequency harmonics if some of the critical components are far away from each other and are connected with inductive traces. The following is a guideline of how to place the critical components and the connections between them in order to minimize the above issues. Start the layout by first placing the power components: 1) Place the input capacitors C3 and C14 and the high side mosfets ,Q1 and Q3 as close to their respective input caps as possible 2) Place the synchronous mosfet,Q4 and the Q3 as close to each other as possible with the intention that the source of Q3 and drain of the Q4 has the shortest length. Repeat this for the Q1 and D1 for the non synchronous. 3) Place the snubber R15 & C13 between Q4 & Q3. Repeat this for R1 and C4 with respect to the Q1 and D1 for the non synchronous. 4) Place the output inductor ,L3 and the output capacitors ,C16 between the mosfet and the load with output capacitors distributed along the slot 1 and close to it. Repeat this for L2 with respect to the C1 for the non synchronous. 5) Place the bypass capacitors, C8 and C19 right next to 12V and 5V pins. C8 next to the 12V, pin 28 and C19 next to the 5V, pin 11. 6) Place the US3007 such that the pwm output drives, pins 27 and 25 are relatively short distance from gates of Q3 and Q4. The non-synch MOSFET must also be situated such that the distance from its gate to the pin 1 of the US3007 is also relatively short. 7) Place all resistor dividers close to their respective feedback pins. 8) Place the 2.5V output capacitor, C18 close to the pin16 of the IC and the 1.5V output capacitor, C17 close to the Q2 MOSFET. Rev. 1.8 12/8/00 US3007 Note: It is better to place the 1.5V linear regulator components close to the 3007 and then run a trace from the output of the regulator to the load. However, if this is not possible then the trace from the linear drive output pin, pin 18 must be run away from any high frequency data signals. It is critical, to place high frequency ceramic capacitors close to the clock chip and termination resistors to provide local bypassing. 9) Place R12 and C10 close to pin 23 and R9 and C5 close to pin 9. 10) Place C9 close to pin 12 Component connections: Note : It is extremely important that no data bus should be passing through the switching regulator section specifically close to the fast transition nodes such as PWM drives or the inductor voltage. Using the 4 layer board, dedicate on layer to GND, another layer as the power layer for the 5V, 3.3V, Vcore, 1.5V and if it is possible for the 2.5V. Connect all grounds to the ground plane using direct vias to the ground plane. Use large low inductance/low impedance plane to connect the following connections either using component side or the solder side. a) C14 to Q3 Drain and C3 to Q1 drain b) Q3 Source to Q4 Drain and Q1 Source to D1 cathode c) Q4 drain to L3 and D1 cathode to L2 d) L3 to the output capacitors, C16 and L2 to the output capacitors, C1 e) C16 to the load, slot 1 f) Input filter L1 to the C16 and C3 g) C1 to Q2 drain h) C17 to the Q2 source I) A minimum of 0.2 inch width trace from the C18 capacitor to pin 16 Connect the rest of the components using the shortest connection possible Rev. 1.8 12/8/00 4-15