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Application Note 42
Implementing the RC5040 and RC5042
DC-DC Converters on Pentium
Introduction
This document describes how to implement a switching volt-
age regulator using an RC5040 or an RC5042 high speed
controller, a power inductor, a Schottky diode, appropriate
capacitors, and external power MOSFETs. This regulator
forms a step down DC-DC converter that can deliver up to
14.5A of continuous load current at voltages ranging from
2.1V to 3.5V. A specific application circuit, design consider-
ations, component selection, PCB layout guidelines and per-
formance evaluation procedures are covered in detail.
In the past 10 years, microprocessors have evolved at such an
exponential rate that a modern chip can rival the computing
power of a mainframe computer. Such evolution has been
possible because of the increasing numbers of transistors that
processors integrate. Pentium CPUs, for example, integrate
well over 5 million transistors on a single piece of silicon.
To integrate so many transistors on a piece of silicon, their
physical geometry has been reduced to the sub-micron level.
As a result of each geometry reduction, the corresponding
operational voltage for each transistor has also been reduced.
This changing voltage for the CPU demands the design of a
programmable power supply—a design that is not com-
pletely re-engineered with every change in CPU voltage.
The operational voltage of CPUs has shown a downwards
trend for the past 5 years: from 5V for the x386 and x486, to
3.3V for Pentium, and 3.1V for Pentium Pro. Furthermore,
emerging chip technologies may require operating voltages
as low as 2.5V. With this trend in mind, Raytheon Electron-
ics has designed the RC5040 and RC5042 controllers. These
controllers integrate the necessary programmability to
address the changing power supply requirements of lower
voltage CPUs.
Previous generations of DC-DC converter controllers were
designed with fixed output voltages adjustable only with a
set of external resistors. In a high volume production envi-
ronment (such as with personal computers), however, a CPU
voltage change requires a CPU board re-design to accommo-
date the new voltage requirement. The integrated 4-bit DAC
in the RC5040 and the RC5042 reads the voltage ID code
from the Pentium Pro microprocessor and configures the sys-
tem to provide the appropriate voltage. In this manner, the
PC board does not have to be re-designed each time the CPU
voltage changes. The CPU can thus automatically configure
its own required voltage.
®
Pro Motherboards
Pentium Pro and OverDrive
Processor Power Requirements
Use Intel's AP-523 Application Note, Pentium® Pro
Processor Power Distribution Guidelines, November 1995
(order number 242764-001), as a basic reference. The speci-
fications contained in this document have been modified
slightly from the original Intel document to include updated
specifications for Pentium Pro microprocessors. Please con-
tact Intel Corporation for specific details.
Input Voltages
Available inputs are +5V 5% and +12V 5%. Raytheon
Electronics' DC-DC converters may use either or both
inputs. Their input voltage requirements are listed in Table 1.
Table 1. Input Voltage Requirements
Controller
Part #
V
CC
RC5040
+5V 5%
RC5042
RC5043
+5V 5%
Pentium Pro DC Power Requirements
Refer to Table 2 for the power supply specifications for
Pentium Pro and Overdrive Processors. For a motherboard
design without a standard Voltage Regulator Module (VRM)
socket, the on-board DC-DC converter must supply a mini-
mum I
P current of 13.9A at 2.5V and 12.4A at 3.3V. For a
CC
flexible motherboard design, the on-board converter must be
able to supply 14.5A maximum I
DC Voltage Regulation
As indicated in Table 2, the voltage level supplied to the
CPU must be within 5% of its nominal setting. Voltage
regulation limits must include:
• Output load ranges specified in Table 2
• Output ripple/noise
• DC output initial voltage set point
• Temperature and warm up drift (Ambient +10 C to +60 C
at full load with a maximum rate of change of 5 C per 10
minutes minimum but no more than 10 C per hour)
• Output load transient with:
Slew rate >30A/ s at the converter pins
Range: 0.3A – I
P Max (as defined in Table 2).
CC
www.fairchildsemi.com
®
MOSFET
MOSFET
Drain
Gate Bias
+5V 5%
+5V 5% or
12V 5%
12V 5%
12V 5%
P.
CC
Rev. 1.1.0
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Table of Contents
Summary of Contents for Fairchild SEMICONDUCTOR RC5040
-
Page 1: Application Note
Application Note 42 Implementing the RC5040 and RC5042 DC-DC Converters on Pentium Introduction This document describes how to implement a switching volt- age regulator using an RC5040 or an RC5042 high speed controller, a power inductor, a Schottky diode, appropriate capacitors, and external power MOSFETs. - Page 2 AN42 Table 2. Intel Pentium Pro and OverDrive Processor Power Specifications CPU Model & Features 150MHz – 256K L2 Cache 166MHz – 512K L2 Cache 180MHz – 256K L2 Cache 200MHz – 256K L2 Cache 200MHz – 512K L2 Cache OverDrive Processors 150 MHz 180 MHz...
- Page 3 APPLICATION NOTE RC5040 and RC5042 Description Simple Step-Down Converter Figure 1. Simple Buck DC-DC Converter Figure 1 illustrates a step-down DC-DC converter with no feedback control. The basic step-down converter serves as the basis for deriving the design equations for the RC5040 and RC5042.
- Page 4 AN42 Main Control Loop OSCILLATOR 4-BIT VREF VID0 VID1 VID2 VID3 High Current Output Drivers The RC5040 contains two identical high current output drivers that use high speed bipolar transistors in a push-pull configuration. Each driver is capable of delivering 1A of cur- rent in less than 100ns.
- Page 5 APPLICATION NOTE Over-Voltage Protection The RC5040 and RC5042 constantly monitor the output voltage for protection against over voltage. If the voltage at the VFB pin exceeds 20% of the selected program voltage, an over-voltage condition is assumed, and the controller dis- ables the output drive signal to the external MOSFET(s).
- Page 6 AN42 2.6 H 0.1 F VREF 0.1 F VID3 VID2 VID1 VID0 OUTEN Figure 4. Synchronous DC-DC Converter Application Schematic Using RC5040 2.6 H 0.1 F 1000 F 1000 F 1000 F RC5042 VREF 0.1 F VID3 VID2 VID1 VID0 Figure 5.
- Page 7 APPLICATION NOTE MOSFET Selection This application requires the use of N-channel, Logic Level Enhancement Mode Field Effect Transistors. The desired characteristics of these components are: • Low Static Drain-Source On-Resistance < 37 m (lower is better) DS,ON • Low gate drive voltage, V 4.5V Table 5.
- Page 8 AN42 MOSFET Gate Bias The MOSFET(s) can be biased using one of two methods: Charge Pump or 12V Gate Bias. Charge Pump (or Bootstrap) Figure 6 employs a charge pump to provide the MOSFET gate bias. The charge pump capacitor, CP, is used as a flying capacitor to boost the voltage of the RC5040 or RC5042 out- put driver.
- Page 9 APPLICATION NOTE Converter Efficiency Losses due to parasitic resistance in the switches, inductor, and sense resistor dominate at high load-current levels. The major loss mechanisms under heavy loads, in order of importance, are: • MOSFET I R Losses • Inductor Losses Efficiency of the converter under heavy loads can be calculated as follows: Efficiency ------------- -...
- Page 10 AN42 2.19W 1.0W 0.65W LOSS 3.3 10 Efficiency -------------------------------------- - 3.3 10 5.815 Selecting the Inductor Selecting the right inductor component is critical in the DC-DC converter application. The inductor’s critical param- eters to consider are inductance (L), maximum DC current ), and coil resistance (R The inductor core material is crucial in determining the amount of current it can withstand.
- Page 11 APPLICATION NOTE where: • V = Input Voltage to the Converter • = Voltage Across the MOSFET = I • V = Forward Voltage of the Schottky Diode • T = The Switching Period of the Converter = 1/f Where f = Switching Frequency.
- Page 12 AN42 Table 8. R for various load currents sense SENSE PC Trace Load,max Resistor (m ) 10.0 11.2 12.4 13.9 14.0 14.5 Discrete Sense Resistor Discrete iron alloy resistors come in a variety of tolerances and power ratings, and are ideal for precision implementa- tions.
- Page 13 APPLICATION NOTE IFBH MnCu Discrete Resistor IFBL Figure 12. Short Circuit Sense Resistor Design Using PC Trace Resistor and Optional Discrete Sense Resistor currents to change. Therefore, combining an embedded resistor with a discrete resistor may be a desirable option. This section discusses a design that provides flexibility and addresses wide tolerances.
- Page 14 AN42 Figure 14A. V Output Waveform for Normal CCQP Operation Condition with V Figure 14B. V Output Waveform for CCQP Output Shorted to Ground The Schottky diode has a power dissipation consideration during the short circuit condition. During normal operation, the diode dissipates power when the power MOSFET is off.
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Page 15: Input Filter
APPLICATION NOTE Table 10. Schottky Diode Selection Table Manufacturer Model # Conditions Philips = 20A; T =25 C PBYR1035 = 20A; T =125 C Motorola = 20A; T =25 C MBR2035CT = 20A; T =125 C Motorola = 15A; T =25 C MBR1545CT = 15A;... -
Page 16: Pcb Layout Guidelines
AN42 Table 11. Bill of Materials for a 14.5A Pentium Pro Motherboard Application C13, C14, C15 Sanyo 6MV1500GX Motorola (note 1) MBR1545CT General Instruments 1N5817 Skynet 320-8107 Skynet 320-6110 M1, M2, M3 Fuji (note 2) 2SK1388 Rsense COPEL A.W.G. #18 R1, R2, R3, R4, R6, Panasonic ERJ-6ENF10.0KV Raytheon... - Page 17 APPLICATION NOTE Figure 16. Example of Proper MOSFETs Placements PC Motherboard Layout and Gerber File A reference design for motherboard implementation of the RC5040 and RC5042 along with the Layout Gerber File and Silk Screen are presented below. The actual PCAD Gerber Good layout Bad layout RC5040...
- Page 18 AN42 APPLICATION NOTE...
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Page 19: Troubleshooting
APPLICATION NOTE Guidelines for Debugging and Performance Evaluations Debugging Your First Design Implementation Use the following procedure to help you debug your design implementation: Note the VID pins settings. They tell you what voltage is to be expected. Do not connect any load to the circuit. While monitoring the output voltage, apply power to the part with current limiting at the power supply. -
Page 20: Performance Evaluation
AN42 4. Premature shut down can be caused by an inappropriate value of sense resistor. See the Sense Resistor section. A poor load regulation can have many causes. You should first check the voltages and signals at the critical pins. The VREF pin should be at the voltage set by the VID pins. - Page 21 APPLICATION NOTE load 1010 10.0 11.0 12.0 13.0 13.9 Load Regulation 0.5 - 13.9A Note: Load regulation is expected to be typically around 0.8%. The load regulation performance for this device under evaluation is excellent. Output Voltage Load Transients Due to Load Current Step This test is performed using Intel P6.0/P6S/P6T Voltage Transient Tester.
- Page 22 AN42 Component Case Temperature Device Description MOSFET K1388 MOSFET K1388 Inductor, Unknown Schottky Diode 2048CT Raytheon RC5040 Input Capacitor 1000 F Cout Output Capacitor 1500 F Note: Case temperatures are all within guidelines. Our guideline is that case temperatures for all components should be below 105 C @25 C Ambient.
- Page 23 APPLICATION NOTE Attachment C Attachment D Summary This application note covers for implementation of a DC-DC converter on a Pentium Pro motherboard using the RC5040 and RC5042. The detailed discussion includes Pentium Pro processor power requirements, RC5040 and RC5042 description, design considerationsn and component selec- tions, layout guidelines and considerations, guidelines for debugging, and performance evaluations.
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Page 24: Appendix A: Directory Of Component Suppliers
Phoenix, Arizona 85036 PH:(602) 897-5056 LIFE SUPPORT POLICY FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR CORPORATION. As used herein: 1. Life support devices or systems are devices or systems...
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