`Walker et a1.
`
`[19]
`
`[11] Patent Number:
`
`5,632,039
`
`[45] Date of Patent:
`
`May 20, 1997
`
`USOOS632039A
`
`[54]
`
`[75]
`
`[73]
`
`[2 1]
`
`[22]
`
`[51]
`[52]
`[5 8]
`
`[56]
`
`CIRCUIT THAT AUTOMATICALLY
`SWITCHES BETWEEN SUPPLYING A
`MICROPROCESSOR WITH A FIRST
`VOLTAGE AND A SECOND VOLTAGE
`
`Inventors: Richard E. Walker, The Woodlands;
`Kurtis J. Bowman, Cypress, both of
`Tex.
`
`Assignee: Compaq Computer Corporation,
`Houston, Tex.
`
`App]. No.: 377,151
`
`Filed:
`
`Jan. 24, 1995
`
`Int. CL.6 ........................................................ G06F 1/26
`US. Cl. ............................................... 395/750; 326/68
`Field of Search ............................. 395/750; 364/492,
`364/707; 323/304, 313, 314, 909; 326/68
`
`References Cited
`
`U.S. PATENT DOCUMENTS
`
`4,992,970
`2/1991 Igarashi ............................... 395/750 X
`5,184,059
`2/1993 Patino et a1.
`....... 320/15
`
`5,283,762
`2/1994 Fujishima .
`365118909
`5,355,073 10/1994 Nguyen .
`320/15
`
`. 361/807
`5,384,692
`1/1995 Jafi'
`
`
`6/1995 MacWLlliams
`5,421,734
`439/59
`....................... 326/68
`5,422,523
`6/1995 Roberts et a1.
`
`OTHER PUBLICATIONS
`
`Press Release, “Intel Unveils Pentium Overdrive CPU”, Jan.
`23, 1995, Intel Corp.
`IntelDX4TM Processor Data Book, Feb. 1994, pp. 1—15,
`7—10, 7—11, Intel Corporation.
`
`104
`
`Primary Examiner—Glenn A. Auve
`Attorney, Agent, or Fim—Pravel, Hewitt, Kimball &
`Krieger
`
`[57]
`
`ABSTRACT
`
`A circuit that automatically switches the power supply
`voltage PVDD provided to a CPU between 3.3 volts and 5
`volts. The circuit detects whether the CPU installed in a
`
`socket is a 3.3-volt part or a S-volt part by determining the
`state of a voltage detect sense pin provided by the socket. If
`the voltage detect sense pin is driven low, that indicates a
`3.3-volt CPU is being used. If a 5-volt CPU is installed, the
`voltage detect sense pin is left floating by the CPU, which
`allows a pullup resistor to pull the voltage detect sense pin
`high. The power supply voltage provided to the CPU is
`regulated through a power field effect transistor (FET). The
`gate of the power FEI‘ is connected to the output of a voltage
`reference source and is coupled to a 12-volt supply signal.
`If the voltage detect sense pin is pulled high, the voltage
`reference source is turned 01f, allowing the 12-volt supply
`signal to drive the gate of the power FET. This in turn allows
`the power FBI to pass a S—volt supply signal to the CPU
`supply signal PVDD. If the voltage detect sense pin is pulled
`low, the voltage reference source is turned on to drive the
`gate of the power FEI‘ to approximately one threshold
`voltage above 3.3 volts. In response, the power FEI‘ passes
`only 3.3 volts to the CPU supply signal PVDD.
`
`18 Claims, 2 Drawing Sheets
`
`
`
`HOST en's
`
`102
`
`BUS CONTROLLER
`MEMORY CONTROLLER
`SYSTEM PERIPHERAL
`
`ISA BUS
`
`120
`
`
`BUFFER
`
`116/
`
`
`
`
`
`PV_D +5v +sz VOLDET
`COMBO
`PERIPHERAL
`
`CHIP
`DISK 134
`
`122
`
`FLDPPY
`CONTROLLER
`
`124
`
`’25
`
`FLOPPY
`
`PARALLEL
`
`[SERIAL
`PIRT
`
`
`APPLE 1023
`
`1
`
`APPLE 1023
`
`
`
`US. Patent
`
`May 20, 1997
`
`Sheet 1 of 2
`
`5,632,039
`
`h.OE
`
`mamhas:
`
`82>
`
`Emhm>w
`
`EoEm—s.
`
`on:.
`
`so»
`
`Eu
`
`..532
`
`No»
`
`we“
`
`VS.
`
`00»
`
`(/0
`
`<2
`
`33w
`
`\-
`uh“
`
`mzm<w_
`
`N:
`
`NW»
`
`m=mx
`
`mm.“
`
`a?3+8.:
`
`$45528E3:
`
`5.59.
`
`5.an
`
`.532
`
`bmh
`
`v2
`
`>33“.
`
`wa
`
`$385.28mam
`
`
`
`:EEEE5555
`
`
`
`535528Ens—ms.
`
`0:.
`
`ON»
`
`mun—”5m
`
`muzwux
`
`99.
`
`mNF
`
`#3521
`
`EEmw.
`
`mEom
`
`$2:
`
`ng
`
`828
`
`EEEEE
`
`n==u
`
`mm“
`
`Wm»
`
`2
`
`
`
`
`
`
`
`
`
`US. Patent
`
`May 20, 1997
`
`Sheet 2 of 2
`
`5,632,039
`
`VFN
`
`>m+
`
`ohm
`
`aa>m.
`
`VNN
`
`Hmngo>.
`
`«hm
`
`new
`
`.............Nm?
`
`................ngszn.
`
`at.
`
`mommvmmom-
`
`
`
`QFN..>~_+
`
`OWNHHU\IV
`
`{
`
`New
`
`>m+
`
`ON
`
`NGE
`
`3
`
`
`
`5,632,039
`
`1
`CIRCUIT THAT AUTOMATICALLY
`SWITCHES BETWEEN SUPPLYING A
`MICROPROCESSOR WITH A FIRST
`VOLTAGE AND A SECOND VOLTAGE
`
`BACKGROUND OF THE INVENTION
`
`1. Field of the invention
`
`The invention relates to controlling a power supply volt—
`age provided to a microprocessor, and more particularly, to
`a circuit that automatically switches between supplying the
`microprocessor with a first voltage or a second voltage.
`2. Description of the Related Art
`Over the past decade,
`the performance and speed of
`microprocessors have improved dramatically. The number
`of transistors that can be fitted onto a microprocessor chip
`number is in the millions. Such densities are allowed pri-
`marily with the use of complementary metal oxide silicon
`(CMOS) technology, which allows for significantly lower
`power consumption over prior bipolar and NMOS technolo-
`gies. However, even with the use of CMOS technology,
`power dissipation by today’s high performance micropro-
`cessors is a significant problem. To reduce power
`consumption, microprocessors such as the 4868L and Pen—
`tium® CPUs from Intel Corporation include built-in power
`management functions. The energy efficient CPUs include a
`stop clock and auto halt mode. In stop clock mode, the clock
`speed of the microprocessor can be reduced or even stopped
`altogether, which reduces the power dissipation of the
`microprocessor when it is idle. The CPU enters into the auto
`halt mode after execution of a halt instruction. This allows
`the microprocessor to be placed into low power mode via
`software.
`Neither of the above features, however, address how the
`power consumption of a microprocessor can be reduced
`while it is active. One popular method of reducing power
`consumption while the microprocessor is running is to
`reduce its power supply voltage from the industry standard
`5 volts down to 3.3 volts. Lower voltages have also proved
`to be necessary as die sizes continue to shrink. The small
`dimensions that exist on a chip require a lower operating
`voltage to avoid problems associated with high current
`densities. Wlth the trend towards 3.3 volt microprocessors
`chip manufacturers have had to provide both microproces—
`sors that operate at 5 volts and 3.3 volts.
`This presents the computer manufacturers with a problem,
`however, as the computer system must be capable of pro
`viding two diflerent power supply voltages to the micropro-
`cessor. One solution is to include a S-volt power supply
`voltage on all computer systems, adding a conventional
`regulator for providing a 3.3 volt power supply voltage in
`the 3.3—volt computer systems. However, this requires that
`the manufacturing process be different for 3.3-volt and
`5—Volt computer systems. Single-part solutions exist where
`the same part can be used with both 3.3-volt and 5-v01t
`microprocessors. However,
`these parts include linear
`regulators, which are relatively expensive components. Thus
`the use of the separate, conventional linear regulator is
`undesirable, as it adds cost
`to the manufacture of the
`computer systems for several reasons.
`
`SUNIMARY OF THE PRESENT INVENTION
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`40
`
`45
`
`50
`
`55
`
`It is an object of the present invention to provide a
`low-cost power supply control circuit that can be used with
`microprocessors that operate at either a first or second
`supply voltage. The power supply control circuit according
`
`65
`
`2
`to the present invention includes regulator circuitry that
`selectively provides a microprocessor supply voltage at a
`first voltage or a second voltage, those voltages preferably
`being 3.3 volts and 5 volts, respectively. The computer
`system preferably includes a socket for receiving a
`microprocessor, and the socket includes a pin referred to as
`the voltage detect sense pin. Microprocessors operating at
`3.3 volts drive the voltage detect sense pin low, whereas
`5—volt microprocessors leave the voltage detect sense pin
`floating, allowing a pullup resistor to pull the pin high. The
`voltage detect sense pin from the microprocessor socket is
`connected to the regulator circuitry in the power supply
`control circuit. The regulator circuitry includes a power field
`efiect transistor (FEI‘), whose drain is preferably connected
`to a S-volt source, and whose source provides the power
`supply voltage to the microprocessor. The gate of the power
`FEI‘ 200 in the preferred embodiment is connected to a
`voltage reference source, which drives the gate of the power
`FET to approximately 12 volts if the voltage detect sense pin
`is pulled high by the pullup resistor, and which drives the
`gate to one threshold voltage of the power FEI‘ above 3.3
`volts if the sense pin is driven low. Thus, if the voltage detect
`sense pin is pulled low, the power FET drives the micro-
`processor supply voltage to 3.3 volts. Otherwise, if the
`voltage detect sense pin is pulled high, the power PET is
`completely turned on and allows the 5-volt voltage to pass
`to the microprocessor supply voltage.
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`A better understanding of the present invention can be
`obtained when the following detailed description of 5 the
`preferred embodiment is considered in conjunction with the
`following drawings, in which:
`FIG. 1 is an exemplary computer system incorporating the
`power supply control circuit according to the present inven—
`tion; and
`FIG. 2 is a schematic diagram of portions of the power
`supply control circuit of Figure I that regulates the voltage
`provided to a microprocessor in the computer system.
`DETAILED DESCRIPTION OF THE
`PREFERRED EMBODIMENT
`
`Referring now to FIG. 1, an exemplary computer system
`C incorporating a power supply control circuit according to
`the present invention is shown. The computer system C
`includes a socket 100 for receiving a host CPU or processor
`101, which is conventionally amicroprocessor such as a486
`or Pentium® processor from Intel Corporation. It is con—
`templated that instead of using the socket 100, the CPU 101
`can be directly soldered to the motherboard. The type of
`microprocessors that can be used with the computer system
`C include the 486$X, 486DX, 486DXZ, 487SX, 486DX4,
`and Pentium® P24T processors. In addition, microproces-
`sors from other manufacturers compatible with the 486
`processor can also be used The 4868X, 486DX, 486DX2,
`and P24T processors operate at 5 volts, while the 486DX4
`operates at 3.3 volts. Certain of the microprocessors from
`the other manufacturers also operate at 3.3 volts. The socket
`100 receives a pin or plurality of pins PVDD, which is the
`microprocessor power supply pin or pins driven to 5 volts or
`3.3 volts, depending on which microprocessor is used. The
`socket 100 also includes a voltage detect sense pin VOL-
`DET. When a 3.3-volt microprocessor is inserted into the
`socket 100, the microprocessor drives the pin VOLDET low.
`If a 5-volt microprocessor is inserted, the pin VOLDET is
`left floating.
`
`4
`
`
`
`5,632,039
`
`3
`Ahost bus 102 is connected to the CPU 101 to act as a first
`bus in the computer system C. A main memory system 104
`is also connected to the host bus 102 to act as the main
`memory of the computer system C. A video system 106 is
`further connected to the host bus 102 to allow for a high
`performance video system.
`A controller 110 is connected between the host bus 102
`and an ISA or Industry Standard Architecture bus 112. The
`controller 110 includes a bus controller portion, a memory
`controller portion and a system peripheral control portion.
`The system peripheral control portion includes certain com-
`mon peripheral devices used in the computer system C such
`as timers. an interrupt controller, and :1 DMA controller. The
`bus controller portion of the controller 110 controls bus
`cycles on the host bus 102 and the ISA bus 112. The memory
`controller portion provides appropriate signals to the
`memory 104, which preferably is made up of dynamic
`random access memories (DRAMs). A nmnber of ISA slots
`116 for receiving interchangeable circuit cards are present
`on the ISA bus 112.
`
`Appropriate buffer and transceiver logic 120 is connected
`between the ISA bus 112 and an X bus 122. which forms an
`additional input/output (I/O) bus in the computer system C.
`A read-only memory or ROM 124, which contains the
`instructions forming the BIOS and other fundamental
`operations. is connected to the X bus 122. A combo periph-
`eral chip 126 is also connected to the X bus 122. The combo
`peripheral chip 126 includes a keyboard controller to receive
`keyboard and pointing device inputs from a user, an inter—
`face for connection to parallel and serial ports 130 to provide
`for certain IIO capabilities, and a hard disk controller for
`interfacing to a hard disk drive 128. The combo peripheral
`chip 136 also includes a real-time clock (RTC) and basic and
`extended CMOS memory. The RTC provides various real-
`time clock functions. and the CMOS memory provides
`storage for various system configuration information.
`Additionally, a floppy disk controller 132 is connected to the
`X bus 122. The floppy disk controller 132 acts as an
`interface between the X bus 122 and a floppy disk drive 134.
`Apower supply circuit 136 is also located in the computer
`system C. The outputs provided by the power supply circuit
`136 include a 12-volt supply signal +12 V, a 5—volt supply
`signal +5 V. and the supply signal PVDD, which varies
`between 3.3 volts and 5 volts depending on the type of the
`CPU 101 used The voltage detect sense pin VOLDET is
`provided to the power supply circuit 136. The power supply
`signal PVDD is provided to the CPU 101. and in accordance
`with the present invention, is automatically set at 3.3 volts
`or 5 volts depending on the state of the pin VOLDET.
`Referring now to FIG. 2. regulator circuitry in the power
`supply circuit 136 for generating the supply signal PVDD is
`shown. The regulator circuitry includes a power n—channel
`enhancement field effect transistor (PEP) 200, whose drain
`is connected to the supply signal +5 V and whose source is
`connected to the supply signal PVDD. A decoupling capaci-
`tor 204 is connected between the drain of the power FE'I‘ 200
`and ground to remove high frequency noise. Decoupling and
`bulk capacitors 224 are connected to the supply signal
`PVDD to maintain the voltage level at PVDD stable. The
`gate of the power FEI‘ 200 is connected to the output pin of
`a voltage reference source 202. Any one of the standard
`voltage reference source chips generally available can be
`used. provided that the reference voltage is as described
`below. though the TL431 is preferred The gate of the power
`FEI‘ 200 is also coupled to the supply signal +12 V through
`a resistor 203. The reference input of the voltage reference
`source 202 is connected to the collector of a bipolar junction
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`40
`
`45
`
`50
`
`55
`
`60
`
`65
`
`4
`transistor (BJT) 210, and the ground pin of the voltage
`reference source 202 is connected to ground. The emitter of
`the BJT 210 is connected to ground and its base is coupled
`to the voltage detect sense pin VOLDET through a resistor
`212. A pullup resistor 214 is connected between the voltage
`detect sense pin VOLDET and the supply signal +5 V. When
`a S—volt CPU 101 is placed into the socket 100, the sense pin
`VOLDET is left floating. As a result. the pullup resistor 214
`is able to pull the sense pin VOLDET to 5 volts. If a 3.3-volt
`CPU 101 is inserted into the socket 100. then the sense pin
`VOLDET is driven low by the CPU 101.
`A resistor 206 is connected between the source of the
`power FET 200 and the collector of the BJT 210. Another
`resistor 208 is connected between the collector of the BJT
`210 and ground. The resistors 206 and 208 form a voltage
`divider circuit to provide a voltage at their common node
`based on 11116 voltage of the supply signal PVDD. In addition.
`a capacitor 216 is connected between the output pin and the
`reference pin of the reference voltage source 202. One side
`of a resistor 220 is also connected to the output pin of the
`voltage reference source 202, and the other side of the
`resistor 220 is connected to one side of a capacitor 218. The
`other side of the capacitor 218 is connected to the reference
`pin of the voltage reference source 202. The capacitors 216
`and 218 and the resistor 220 function to stabilize the voltage
`generated on the output pin of the voltage reference source
`202. Any noise glitch occurring on the reference pin of the
`voltage reference source 202 is filtered by the combination
`of the resistor 220 and the capacitors 216 and 218.
`If the sense pin VOLDET is pulled high by the resistor
`214, the BJT 210 is turned on, thereby pulling the reference
`pin of the voltage reference source 202 to approximately the
`collector-to-emitter saturation voltage of the BJT 210. which
`is approximately 0.2 to 0.3 volts. This turns the voltage
`reference source 202 off, which allows the supply signal +12
`V to drive the gate of the power FET 200 to approximately
`12 volts. As a result, the voltage of the supply signal +5 V
`completely passes through the power FEI‘ 200 to drive the
`supply signal PVDD to 5 volts.
`If a 3.3-volt CPU 101 is installed and the sense pin
`VOLDET is driven low. the BJT 210 is turned ofl. As a
`result, the voltage provided to the reference pin of the
`voltage reference source 202 is developed by the voltage
`divider formed from the resistors 206 and 208. The voltage
`at the reference pin of the voltage reference source 202 is
`thus dependent upon the power supply voltage PVDD. At
`steady state. the voltage at the reference pin of the voltage
`reference source 202 is driven to about 2.5 volts. In response
`to this voltage, the voltage reference source 202 drives the
`gate of the power FEI‘ 200 to approximately one threshold
`voltage (VT) above 3.3 volts. The threshold voltage V, of the
`power FEI‘ 200 ranges from3 to 10 volts. Consequently, due
`to the gate-to—source threshold voltage Vof the power FEI‘
`200, the voltage at the source of the power FEI‘ 200 is
`limited to approximately 3.3 volts. A feedback path exists
`from the regulated supply signal PVDD through the resistor
`206 to the reference pin of the voltage reference source 202,
`which allows the supply signal PVDD to be maintained at a
`relatively stable 3.3 volts.
`Optional zero ohm resistors 222 are inserted between the
`supply signal +5 V and the supply signal PVDD when the
`power PET 200 and all its associated circuitry are not
`installed. When optional resistors 22 are used instead of the
`power FET 200. the computer system C can be used only
`with 5-volt microprocessors.
`Thus, a circuit has been described that automatically
`switches the power supply voltage provided to a CPU,
`
`5
`
`
`
`5,632,039
`
`5
`referred to as supply signal PVDD, between 3.3 volts and 5
`volts. The circuit detects whether the CPU installed in a
`socket is a 3.3-volt part or a S-volt part by determining the
`state of a voltage detect sense pin provided by the socket. If
`the voltage detect sense pin is driven low, that indicates a
`3.3-volt CPU is being used. If a S-volt CPU is installed, the
`voltage detect sense pin is left floating by the CPU, which
`allows a pullup resistor to pull the voltage detect sense pin
`high. The power supply voltage provided to the CPU is
`regulated through a power field effect transistor (FET). The
`gate of the power FEI‘ is connected to the output of a voltage
`reference source and is coupled to a 12-volt supply signal.
`If the voltage detect sense pin is pulled high, the voltage
`reference source is turned off, allowing the 12-volt supply
`signal to drive the gate of the power FET. This in turn allows
`the power FET to pass a 5—volt supply signal to the CPU
`supply signal PVDD. If the voltage detect sense pin is pulled
`low, the voltage reference source is turned on to drive the
`gate of the power FET to approximately one threshold
`voltage above 3.3 volts. In response, the power FET passes
`only 3.3 volts to the CPU supply signal PVDD.
`The foregoing disclosure and description of the invention
`are illustrative and explanatory thereof, and various changes
`in the size, shape, materials, components, circuit elements,
`wiring connections and contacts, as well as in the details of
`the illustrated circuitry and construction and method of
`operation may be made without departing from the spirit of
`the invention.
`We claim:
`1. A circuit for automatically switching a power supply
`voltage provided to a microprocessor used in a computer
`system between a first voltage and a second voltage, said
`first voltage being greater than said second voltage, wherein
`the computer system includes a power supply having a first
`power supply output providing the first voltage, and wherein
`the microprocessor provides a voltage detect sense signal
`pin for indicating whether the microprocessor requires the
`power supply voltage at the first voltage or the second
`voltage, the voltage detect sense signal being at a first state
`to indicate the first voltage, and the voltage detect sense
`signal being at a second state to indicate the second voltage,
`the circuit comprising:
`a feedback circuit responsive to the voltage detect sense
`signal and providing an output signal, said output
`signal being driven to a third voltage if the voltage
`detect sense signal is at the first state, and said output
`signal being driven to a fourth voltage if the voltage
`detect sense signal is at the second state; and
`a field efiect transistor having a gate driven by said output
`signal, a drain connected to the first power supply
`output, and a source coupled to a microprocessor power
`supply voltage pin wherein the field effect transistor
`drives the microprocessor power supply voltage to the
`first voltage if said output signal is at said third voltage
`and to the second voltage if said output signal is at said
`fourth voltage.
`2. The circuit of claim 1, wherein said field elfect tran-
`sistor has a threshold voltage, wherein said third voltage is
`approximately one threshold voltage greater than said first
`voltage, and wherein said fourth voltage is approximately
`one threshold voltage greater than said second voltage.
`3. The circuit of claim 2, wherein said first voltage is
`approximately 5 volts and said second voltage is approxi-
`mately 3.3 volts.
`4. The circuit of claim 2, wherein said feedback circuit
`includes:
`
`a voltage reference source having an output pin and a
`reference pin, said output pin providing said output
`signal; and
`
`6
`a driver circuit responsive to said voltage detect sense
`signal and coupled to said reference pin for driving said
`reference pin to a predetermined voltage if the voltage
`detect sense signal is at the second state, wherein said
`reference pin being at said predetermined voltage
`causes said voltage reference source to drive said
`output signal to said fourth voltage.
`5. The circuit of claim 4, wherein the power supply
`includes a second computer system power supply output
`providing a second power supply voltage, and wherein said
`feedback circuit further includes:
`
`a first resistor connected between said output pin of said
`voltage reference source and said second computer
`system power supply output. wherein said driver circuit
`drives said reference pin to turn off said voltage refer-
`ence source if the voltage detect sense signal is at the
`first state, and wherein said second computer system
`power supply voltage drives said output signal to said
`third voltage through said first resistor if said voltage
`reference source is turned off.
`6. The circuit of claim 5, wherein said driver circuit
`includes:
`
`a second resistor connected between the microprocessor
`power supply voltage pin and said reference pin;
`a third resistor connected between said reference pin and
`a ground plane; and
`a transistor connected to said reference pin and coupled to
`the voltage detect sense signal pin, said transistor
`driving said reference pin low if the voltage detect
`sense signal is at the first state, said transistor being
`turned oif if the voltage detect sense signal is at the
`second state, wherein said third resistor has a resistance
`in proportion to said second resistor to provide a
`voltage at said reference pin such that said output pin
`is driven to said fourth voltage when said transistor is
`turned of.
`7. The circuit of claim 6, wherein said transistor is a
`bipolar junction transistor having a collector connected to
`said reference pin, a base coupled to said voltage detect
`sense signal pin, and an emitter connected to said ground
`plane.
`8. The circuit of claim 7, wherein said first voltage is
`approximately 5 volts and said second voltage is approxi—
`mately 3.3 volts.
`.
`9. The circuit of claim 1, wherein the microprocessor
`drives the voltage detect sense signal low to indicate that the
`microprocessor requires the microprocessor power supply
`signal at the second voltage, and wherein the microprocessor
`leaves the voltage detect sense signal undriven to indicate
`that the microprocessor requires the microprocessor power
`supply signal at the first voltage, the circuit further com-
`prising:
`a pullup resistor connected to the voltage detect sense
`signal pin for pulling the voltage detect sense signal
`high if the voltage detect sense signal is undriven by the
`microprocessor.
`10. A computer system, comprising:
`a socket having a voltage detect sense pin and a power
`supply pin;
`a microprocessor having a plurality of pins for insertion
`into said socket, one of said microprocessor pins being
`connected to said voltage detect sense pin and-another
`of said microprocessor pins being connected to said
`power supply pin, wherein said microprocessor drives
`said voltage detect sense pin to a first state if said
`microprocessor requires said power supply pin to be
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`4O
`
`45
`
`50
`
`55
`
`65
`
`6
`
`
`
`5 632,039
`
`7
`driven to a first voltage, and wherein said micropro-
`cessor drives said voltage detect sense pin to a second
`state if said microprocessor requires said power supply
`pin to be driven to a second voltage. said first voltage
`being greater than said second voltage;
`a power supply having a first power supply output for
`providing said first voltage; and
`a circuit coupled to said power supply and said socket for
`automatically switching said power supply pin between
`said first voltage and said second voltage, including:
`a feedback circuit coupled to said voltage detect sense
`pin for providing an output signal, said output signal
`being driven to a third voltage if said voltage detect
`sense pin is at said first state, and said output signal
`being driven to a fourth voltage if said voltage detect
`sense pin is at said second state; and
`a field effect transistor having a gate driven by said
`output signal. a drain connected to said first power
`supply output. and a source coupled to said power
`supply pin, wherein said field efiect transistor drives
`said power supply pin to said first voltage if said
`output signal is at said third voltage and to said
`second voltage if said output signal is at said fourth
`voltage.
`11. The computer system of claim 10, wherein said field
`effect transistor has a threshold voltage, wherein said third
`voltage is approximately one threshold voltage greater than
`said first voltage. and wherein said fourth voltage is approxi-
`mately one threshold voltage greater than said second volt-
`age.
`12. The computer system of claim 11, wherein said first
`voltage is approximately 5 volts and said second voltage is
`approximately 3.3 volts.
`13. The computer system of claim 11. wherein said
`feedback circuit includes:
`
`a voltage reference source having an output pin and a
`reference pin, said output pin providing said output
`signal; and
`a driver circuit coupled to said voltage detect sense pin
`and coupled to said reference pin for driving said
`reference pin to a predetermined voltage if said voltage
`detect sense pin is at said second state. wherein said
`reference pin being at said predetermined voltage
`causes said voltage reference source to drive said
`output signal to said fourth voltage.
`14. The computer system of claim 13, wherein said power
`supply provides a second computer system power supply
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`40
`
`45
`
`8
`output providing a second power supply voltage, and
`wherein said feedback circuit further includes:
`
`a first resistor connected between said output pin of said
`voltage reference source and said second computer
`system power supply output, wherein said driver circuit
`drives said reference pin to turn off said voltage refer-
`ence source if the voltage detect sense signal is at said
`first state, and wherein said second computer system
`power supply voltage drives said output signal to said
`third voltage through said first resistor if said voltage
`reference source is turned oil”.
`15. The computer system of claim 14, wherein said driver
`circuit includes:
`a second resistor connected between said source of said
`field effect transistor and said reference pin;
`a third resistor connected between said reference pin and
`a ground and
`a transistor connected to said reference pin and coupled to
`said voltage detect sense pin, said transistor driving
`said reference pin low if said voltage detect sense pin
`is at said first state, said transistor being turned off if
`said voltage detect sense pin is at said second state,
`wherein said third resistor has a resistance in proportion
`to said second resistor to provide a voltage at said
`reference pin such that said output pin is driven to said
`fourth voltage when said transistor is turned off.
`16. The computer system of claim 15, wherein said
`transistor is a bipolar junction transistor having a collector
`connected to said reference pin, a base coupled to said
`voltage detect sense pin, and an emitter connected to said
`ground plane.
`17. The computer system of claim 16. wherein said first
`voltage is approximately 5 volts and said second voltage is
`approximately 3.3 volts.
`18. The computer system of claim 10, wherein said
`microprocessor drives said voltage detect sense pin low to
`indicate that said microprocessor requires said power supply
`pin to be driven at said second voltage, and wherein said
`microprocessor leaves said voltage detect sense pin undriven
`to indicate that said microprocessor requires said power
`supply pin to be driven at said first voltage, said circuit
`further comprising:
`a pullup resistor connected to said voltage detect sense pin
`for pulling said voltage detect sense pin high if said
`voltage detect sense pin is undriven by said micropro—
`cessor.
`
`7
`
`
`
`
`
`UNITED STATES PATENT AND TRADEMARK OFFICE
`CERTIFICATE OF CORRECTION
`
`PATENT N0.
`
`:
`
`5,632,039
`
`DATED
`
`: May 20, 1997
`
`lNVENTOR‘S): Richard E. Walker and Kurtis J. Bowman
`
`It is certified that error appears in the above-identified patent and that said Letters Patent is hereby
`corrected as shown below:
`
`In column 5,
`
`line 35, claim 1, please delete "signal".
`
`line 36, claim 1, please insert ——communicating a
`In column 5,
`voltage detect sense signal-- after ”for".
`5
`
`,
`
`line 51, claim 1, please delete "voltage".
`
`In column
`In column 6
`
`In column
`
`In column
`
`6
`6
`
`,
`,
`
`,
`
`line 24, claim 6, please delete "voltage".
`6
`line 28, claim
`
`, please delete "signal".
`
`line 40, claim 7, please delete "signal".
`
`In column 6,
`
`line 54, claim 9, please delete "signal".
`
`In column 6,
`
`lines 58 and 59, claim 10, please delete "a socket
`
`having a voltage detect sense pin and a power supply pin;".
`
`In column 6,
`
`line 60, claim 10, please replace "plurality of
`
`pins for insertion into said socket, one of said microprocessor pins
`
`being connected to said voltage detect sense pin and another of said
`
`microprocessor pins being connected to said power supply pin," with
`
`-—voltage detect sense pin and a power supply pin,——.
`
`Arrest:
`
`Signed and Sealed this
`
`Sixth Day of October, 1998
`
`60144 W
`
`BRUCE LEHMAN
`
`Arresting Ojfiz'er
`
`
`Crmmm'rinner (If Palem‘s and Trademarkn
`
`
`
`8
`
`