`
`(12) United States Patent
`Shearon et al.
`
`(10) Patent No.:
`(45) Date of Patent:
`
`US 7,023,187 B2
`Apr. 4, 2006
`
`(54) INTEGRATED CIRCUIT FOR GENERATING
`A PLURALITY OF DIRECT CURRENT (DC)
`OUTPUT VOLTAGES
`
`75
`O
`O
`(75) Inventors: Yip BSE Ely in
`N Ea . SerraZZa, SomerV1lle,
`
`0
`-
`(73) Assignee: Intersil Americas Inc., Milpitas, CA
`(US)
`
`(*) Notice:
`
`Subject to any disclaimer, the term of this
`patent is extended or adjusted under 35
`U.S.C. 154(b) by 559 days.
`(21) Appl. No.: 10/213,766
`
`(22) Filed:
`(65)
`
`Aug. 7, 2002
`Prior Publication Dat
`
`O DO
`
`US 2003 FOO3526O A1
`
`Feb. 20, 2003
`
`Related U.S. Application Data
`(60) Provisional application No. 60/312,826, filed on Aug.
`16, 2001.
`
`(51) Int. Cl.
`(2006.01)
`H02M 3/158
`(52) U.S. Cl. ....................... 323/266; 323/267; 323/901
`(58) Field of Classification Search .................. 307/82,
`307/29, 77,65; 363/65, 49, 21.01, 267,901,
`363 (266. 271
`S
`lication file f
`let
`h hist
`s
`ee appl1cauon Ille Ior complete searcn n1story.
`References Cited
`
`(56)
`
`U.S. PATENT DOCUMENTS
`2.929,924. A * 3/1960 Miller ........................ 330/145
`4,313,155 A
`1, 1982 Bock et al.
`... 363.49
`4,361,865 A * 11/1982 Shono ............
`... 363.19
`4,504,898 A
`3, 1985 Pilukaitis et al.
`... 363.49
`4,628.426 A * 12/1986 Steigerwald ...
`... 363.17
`4,887,199 A * 12/1989 Whittle ........................ 363/49
`4,935,858 A
`6/1990 Panicali ................... 363.21.01
`
`5,267,135 A * 11/1993 Tezuka et al. ................ 363.49
`5,307,004 A * 4/1994 Carsten .........
`... 323,222
`5,400.239 A * 3/1995 Caine .....
`... 363.67
`5,455,501 A * 10/1995 Massie
`... 323,267
`5,715,153 A * 2/1998 Lu ................
`... 363.65
`5,861,737 A *
`1/1999 Goerke et al. .
`... 323,282
`5,886,508 A * 3/1999 Jutras ...............
`... 323,267
`5,903,138 A *
`5/1999 Hwang et al. ........
`... 323,266
`5.991,168 A * 11/1999 Farrington et al. ........... 363/16
`6,067.241 A
`5/2000 Lu ......................
`... 363.65
`6,087,817 A * 7/2000 Varga
`... 323,282
`6,195.275 B1
`2/2001 Lu .........
`363.65
`6, 198,642 B 1
`3/2001 Kociecki ..................... 363/37
`
`(Continued)
`OTHER PUBLICATIONS
`Lokhandwala, Adnan M. and Sudip K. Mazumder. “Discrete
`Validation of Smart Power ASIC (SPIC) for a Distributed
`Power System”. 2004 35th Annual IEEE Power Electronics
`Specialists Conference.*
`
`- 0
`
`(Continued)
`Primary Examiner Brian Sircus
`Assistant Examiner—Andrew Deschere
`(74) Attorney, Agent, or Firm Allen, Dyer, Doppelt,
`Milbrath & Gilchrist, P.A.
`
`(57)
`
`ABSTRACT
`
`A cascaded DC R St. architecture has an p.
`converter stage and a downstream converter stage, w 1c
`derives its input Voltage from the upstream stage. Cascading
`the two converter stages enables functionality of control and
`monitoring (including soft start and overcurrent detection)
`circuitry of the upstream stage to be used for the downstream
`stage, to reduce chip area, cost, and complexity. A Voltage
`window regulator in the downstream converter ensures that,
`during shutdown, its output Voltage will be maintained
`within a prescribed window of its regulated output Voltage,
`so that no soft start delay is needed when the second
`converter stage is turned back on.
`
`9 Claims, 3 Drawing Sheets
`
`
`
`
`
`
`
`
`
`
`
`VOAGE
`REF
`ERROR
`PW
`AMP COMPAROR
`
`35
`V
`NHIBT
`
`
`
`========ces---------------
`- 114 : 112
`OSCILLATOR
`-/
`
`
`
`-
`
`- - - - - - - - -
`
`-22
`
`INHIBIT
`OGIC
`36.
`WENOW
`ARAOR 4
`REGULATOR-270
`
`22
`
`Samsung Electronics Co., Ltd.
`Ex. 1047, p. 1
`
`
`
`US 7,023,187 B2
`Page 2
`
`U.S. PATENT DOCUMENTS
`6,222,352 B1
`4/2001 Lenk .......................... 323,267
`6,297,976 B1 102001 Isono ........................
`6,430,070 B1* 8/2002 Shi et al. ...................... 363/97
`6,469,478 B1 * 10/2002 Curtin ........
`323,266
`6,515,880 B1* 2/2003 Evans et al. .................. solo
`6,611436 B1* 8/2003 Nishida et al. .......... 363/21.07
`6,756,772 B1* 6/2004 McGinnis ...
`... 323,225
`6,771,052 B1* 8/2004 Ostojic ....................... 323,266
`6,813,170 B1* 11/2004 Yang ....................... 363.56.09
`6,838,861 B1
`1/2005 Testin ......................... 323,267
`
`
`
`OTHER PUBLICATIONS
`U.S. Appl. No. 09/442,299, entitled: Active Decoupling and
`Power Management Circuit for Line-Powered Ringing Gen
`erator
`U.S. Appl. No. 09/378,382, entitled: Power-Limited Remote
`Termination Converter with Wetting Current and Emer
`gency Power Operation for Digital Data Services Equip
`ment.
`
`* cited by examiner
`
`Samsung Electronics Co., Ltd.
`Ex. 1047, p. 2
`
`
`
`U.S. Patent
`
`Apr. 4, 2006
`
`Sheet 1 of 3
`
`US 7,023,187 B2
`
`
`
`
`F – – – – – – –
`
`
`
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`
`
`||||
`
`| |
`
`1HV
`HOJEd
`
`7 |
`
`30N}}}}}}}}
`
`Samsung Electronics Co., Ltd.
`Ex. 1047, p. 3
`
`
`
`
`POWER-ON
`RESET (POR)
`
`
`FIG. 2 “=~ 4g
`
`
`VOLTAGE
`REF|ERROR
`
`
`AMP
`
`
`
`| 114
`
`12~@
`
`OSCILLATOR}
`
`
` 134
`
`yuayed‘SN
`
`
`9007‘pr‘Ady
`€JO799S
`
`7HL8I€Z0°LSA
`
`Samsung Electronics Co., Ltd.
`Ex. 1047, p. 4
`
`
`
`-_' VT("/SNS2")
`
`1.30
`
`800m
`
`300m
`
`-200m
`
`SECOND DC-T0-DC
`CONVERTER("SLAVE")
`
`SOFT START
`
`
`30 1 VT('/SNS1")
`
`
`
`2.0
`
`41.0
`
`FIRST DC-TO-DC
`CONVERTER ("MASTER")
`
`SOFT START
`
`
`0.0
`300u
`600u
`900u
`1.2m
`1.5m
`
`TIME (s)
`
`FIG. 3
`
`yuayed‘SN
`
`
`9007‘pr‘Ady
`¢JO¢€9S
`
`7HL8I€Z0°LSA
`
`Samsung Electronics Co., Ltd.
`Ex. 1047, p. 5
`
`
`
`US 7,023,187 B2
`
`1.
`INTEGRATED CIRCUIT FOR GENERATING
`A PLURALITY OF DIRECT CURRENT (DC)
`OUTPUT VOLTAGES
`
`CROSS-REFERENCE TO RELATED
`APPLICATION
`
`The present application claims the benefit of co-pending
`Provisional Patent Application, Ser. No. 60/312,826, filed
`Aug. 16, 2001, entitled: “Integrated Circuit for Generating a
`Plurality of Direct Current (DC) Output Voltages.” by W.
`Shearon et al. assigned to the assignee of the present
`application and the disclosure of which is incorporated
`herein.
`
`FIELD OF THE INVENTION
`
`The present invention relates in general to electronic
`circuits and components therefor, and is particularly directed
`to a new and improved dual cascaded, buck mode DC power
`Supply architecture for generating a plurality of DC voltages
`from a single Supply Voltage, and reducing the complexity of
`circuitry used to control the operation of multiple power
`Supply stages.
`
`BACKGROUND OF THE INVENTION
`
`10
`
`15
`
`25
`
`2
`voltage 18. As further shown in FIG. 1, the DC-DC con
`troller 10 may include an overcurrent detector 19 coupled
`via resistor 23 to the VCC bias voltage terminal, and to node
`25. A shut down circuit 22 is controlled by the output of the
`overcurrent detector, so as to controllably interrupt operation
`of the power supply in the event of an overcurrent condition.
`In a number of situations, it may be necessary to provide
`one or more operating Voltages that are different from the
`available Supply Voltage on a single card. In at least one
`application, such as a dual-data-rate (DDR) memory system
`employing DDR random access memories (DRAMs), two
`Supply Voltages are required. Typically, a second Supply
`voltage will be a prescribed fraction (e.g., one-half) of a first
`Supply Voltage, and generally may not exceed the first
`Supply Voltage.
`For improved integration density, where the DC power
`Supply is regulated by an integrated circuit, it is desirable to
`combine control functions for the multiple power Supplies in
`a single IC. Although implementing a multi Voltage Supply
`may be a technical challenge, the benefits of efficiency
`encourage its pursuit. One straightforward way to configure
`a dual Voltage converter is to simply fabricate two discrete
`circuits of the type, such as that shown in FIG. 1, on a
`common motherboard. A similar approach is described in
`the U.S. Pat. No. 6,067.241 to Q. Lu, entitled “Dual-Output
`DC-DC Power Supply.” Lu proposes cascading two types of
`DC converters—a forward DC-DC converter and a buck
`converter in order to realize a half-brick sized power
`Supply.
`Now although such a doubled DC converter architecture
`may provide two different Voltages, each Supply is effec
`tively a discrete, stand-alone circuit, having its own dedi
`cated controller. This fact, coupled with the large size and
`complexity of the soft start and overcurrent detection cir
`cuitry for each converter, make the resulting multi Voltage
`Supply configuration relatively complex, expensive, as well
`as requiring a significant amount of chip area. Moreover,
`implementing a pair of discrete converters of the type
`described in the Lu patent is problematic at best, due to its
`use of a forward DC-DC converter circuit, which contains a
`transformer. As such, this type of DC power Supply archi
`tecture is not practical for powering highly integrated elec
`tronic components, such as DDR DRAMs, and the like.
`
`SUMMARY OF THE INVENTION
`
`In accordance with the present invention, problems of
`multi DC-DC converter architectures, including those
`described above, are effectively obviated by a multi (dual)
`Voltage power Supply architecture, in which an upstream
`buck converter stage is coupled in cascade with a down
`stream buck converter stage. Such that the downstream
`converter its input voltage from the output of the upstream
`converter, and generates an output DC voltage that is a
`prescribed fraction of that input voltage. In addition, the
`manner in which the two buck converter stages are cascaded
`enables the functionality of the control and monitoring
`circuitry (e.g., soft start and overcurrent detection circuitry)
`of upstream converter to be employed for the downstream
`converter.
`Since the downstream converter stage derives all of its
`Supply current from the output voltage produced by the
`upstream stage, the overcurrent detector for the downstream
`converter stage can be eliminated. Instead, an overcurrent
`detector in the upstream buck converter's DC-DC controller
`effectively serves both converter stages. This means that
`only a single overcurrent set resistor and associated terminal
`
`30
`
`35
`
`40
`
`45
`
`Electrical power for an integrated circuit (IC) is typically
`supplied by one or more direct current (DC) power sources,
`such as a buck-mode, pulse width modulation (PWM)
`DC-DC converter of the type diagrammatically shown in
`FIG. 1. In the illustrated buck-mode converter, a DC-DC
`controller 10 switchably controls the turn-on and turn-off of
`a pair of power Switching devices, respectively depicted as
`an upper power MOSFET device 20 and a lower power
`MOSFET device 30. These power MOSFET switching
`devices have their drain-source paths coupled in series
`between first and second bias supply voltages (VCC and
`ground (GND)). A common or phase voltage node 25
`between the two power MOSFETs 20/30 is coupled through
`an inductor 40 to a capacitor 50, which is coupled to a
`reference voltage terminal (GND). The connection 45
`between inductor 40 and capacitor 50 serves as an output
`node from which a desired (regulated) DC output voltage
`Vout is derived.
`The buck converter’s DC-DC controller 10 includes a pair
`of gate driver circuits 11 and 12, which controllably turn
`respective switching devices 20 and 30 on and off, in
`accordance with a pulse width modulation (PWM) switching
`waveform produced by a comparator 13. The upper MOS
`50
`FET device 20 is turned on and off by an upper gate
`Switching signal UG applied by the gate driver 11 to the gate
`of the MOSFET device 20, and the MOSFET device 30 is
`turned on and off by a lower gate Switching signal LG
`applied by the gate driver 12 to the gate of the MOSFET
`55
`device 30.
`To produce the PWM waveform, comparator 13 compares
`the signal level of a periodic reference waveform, such a
`sawtooth signal Supplied by a Sawtooth generator 14, with a
`reference voltage output by an error amplifier 15. The
`frequency of the PWM waveform corresponds to that of the
`periodic waveform supplied by generator 14, while the duty
`cycle of the PWM signal is controlled by the output of the
`error amplifier 15. For this purpose, the error amplifier 15
`compares a fraction of the output voltage Vout at the output
`node 45, as derived by voltage divider 16, and coupled
`through a soft start circuit 17, with prescribed reference
`
`60
`
`65
`
`Samsung Electronics Co., Ltd.
`Ex. 1047, p. 6
`
`
`
`US 7,023,187 B2
`
`5
`
`10
`
`15
`
`25
`
`30
`
`3
`on the IC package is required. The cascade connection
`between the two converters also satisfies the requirement
`that the downstream converter's output voltage not exceed
`the upstream converters output Voltage.
`In addition, since the downstream converter stage derives
`its input voltage from the upstream converter stage, an error
`amplifier used to generate the PWM pulse train that controls
`turn on and turn off of the power switching devices of the
`downstream converter stage will effectively continuously
`track a prescribed fraction (e.g., one-half) of the upstream
`converters output Voltage, including after Soft start of the
`upstream converter stage. As a result, soft-start characteris
`tics of the upstream converter stage are effectively mir
`rored in the downstream converter stage, eliminating the
`need for a separate soft start circuit in the downstream stage.
`In addition, the downstream converter stage is configured
`to be selectively disabled or shut down by an external signal.
`To ensure that the output voltage of the downstream con
`verter stage will not drift too far away from its intended
`value, which might otherwise prohibit a soft start after shut
`down is concluded (unless fairly complex Voltage detection
`circuitry is employed), the downstream converter stage
`employs a Voltage window or keep alive regulator. This
`Voltage window regulator receives a Voltage proportional to
`the output voltage produced by the downstream converter
`stage, and an externally supplied shut down control signal.
`The use of an external shutdown signal makes it possible to
`selectively shut down the second DC-to-DC converter, inde
`pendently of the upstream converter stage. This reduces a
`limitation of conventional buck-mode PWM converters,
`which typically consume a significant amount of power,
`even when not being used.
`Thus, one or both converter stages may be shut down
`when not in use, with the voltage window regulator of the
`downstream converter stage maintaining its output voltage
`within a prescribed voltage window, to eliminate the need
`for a soft start delay when the second converter is turned
`back on. This is possible since, during shut down, loading on
`the output voltage is typically light, allowing a relatively
`simple, light-duty regulator to be used for the window
`regulator. As a non-limiting example, the downstream con
`verter stage's window regulator may be implemented using
`a low cost circuit comprising a resistor and a linear regulator.
`
`4
`implementation example shown and described here is
`intended to Supply only those specifics that are pertinent to
`the present invention, so as not to obscure the disclosure
`with details that are readily apparent to one skilled in the art
`having the benefit of present description. Throughout the
`text and drawings like numbers refer to like parts.
`Attention is now directed to FIG. 2, which diagrammati
`cally illustrates the architecture of a multi (dual) buck-mode
`PWM power supply in accordance a non-limiting, but pre
`ferred embodiment of the present invention. As described
`briefly above and as will be detailed hereafter, the multi
`Voltage power Supply according to the invention is formed
`of a plurality of cascaded buck converter stages. Because of
`the manner in which the two converters are cascaded, the
`downstream converter derives its input voltage from the
`output of the first converter, and is operative to generate an
`output DC voltage that is a prescribed fraction (one-half, as
`a non-limiting example) of that input Voltage. Moreover, this
`cascading allows control and monitoring functionality (e.g.,
`soft start and overcurrent detection circuitry) of the down
`stream converter to be consolidated with the operation of the
`first converter.
`To this end, the multi stage power Supply of the invention
`(shown as a dual stage converter) comprises a first (up
`stream) DC-DC converter 100 having its output cascaded (in
`an inductorless manner (e.g., without a coupling transformer
`therebetween)) with a second (downstream) DC-DC con
`verter 200, each of which may be configured as a buck mode
`converter of the type shown in FIG. 1. Upstream converter
`100 includes a pair of electronic power switching devices,
`respectively shown as an upper power MOSFET device 120
`and a lower power MOSFET device 130, having their
`drain-source paths coupled in series between VCC and
`GND. A phase voltage node 125 between FETs 120/130 is
`coupled through an inductor 140 to a capacitor 150 refer
`enced to GND.
`The connection 145 between inductor 140 and capacitor
`150 serves as an upstream output node from which a first
`regulated DC output voltage Vout1 is derived. For the
`non-limiting example of Supplying a regulated Voltage to a
`DDR DRAM, the first, relatively larger output voltage Vout1
`may provide a V,
`supply voltage to the DRAM. As will
`be described, this first regulated DC output voltage Vout1 is
`provided as the input voltage to the downstream converter
`stage 200. As will be described, with downstream converter
`stage 200 receiving its input Voltage from upstream con
`verter stage 100, an error amplifier that generates the PWM
`pulse train that controls turn on and turn off of MOSFET
`Switching circuits of the downstream converter stage will
`effectively continuously track a prescribed fraction of the
`upstream converter's output voltage Vout1, including after
`soft start of the upstream converter stage. This enables the
`soft-start characteristics of upstream converter stage 100 to
`be effectively mirrored in the downstream DC-to-DC con
`verter stage, eliminating the need for a separate Soft start
`circuit in the downstream stage.
`Upstream buck converter 100 includes a gate control logic
`circuit 110, which Supplies Switching control signals to a
`pair of gate driver circuits 111 and 112, for controllably
`turning respective switching devices 120 and 130 on and off,
`in accordance with a PWM switching waveform produced
`by a PWM comparator 113 and applied to its PWM input.
`Gate driver circuit 111 is coupled with an associated bias
`diode and capacitor network containing diode 124 and
`capacitor 126, and gate driver circuit 112 is coupled with an
`associated capacitor 132. To produce the PWM switching
`waveform, PWM comparator 113 compares the signal level
`
`35
`
`40
`
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`45
`
`FIG. 1 diagrammatically illustrates a conventional buck
`mode PWM power supply:
`FIG. 2 diagrammatically illustrates a dual buck-mode
`PWM power supply according to the present invention; and
`FIG. 3 shows timing diagrams illustrating transient
`responses of output voltages of the dual buck-mode PWM
`power supply of FIG. 2.
`
`50
`
`DETAILED DESCRIPTION
`
`55
`
`Before describing a non-limiting, but preferred embodi
`ment of the dual buck-mode PWM power supply of the
`present invention, it should be observed that the invention
`resides primarily in an arrangement of conventional DC
`60
`power Supply circuit and control components, and the man
`ner in which they are integrated together to realize a shared
`control, multi-voltage power Supply architecture of the type
`described briefly above. It is to be understood that the
`present invention may be embodied in a variety of other
`implementations, and should not be construed as being
`limited to only that shown and described herein. Rather, the
`
`65
`
`Samsung Electronics Co., Ltd.
`Ex. 1047, p. 7
`
`
`
`US 7,023,187 B2
`
`5
`
`10
`
`15
`
`25
`
`5
`of a first periodic reference waveform d1, supplied by a dual
`phase sawtooth signal generator 114, with a Voltage output
`by a duty cycle-controlling error amplifier 115.
`Dual phase sawtooth signal generator 114 is shown as
`comprising an oscillator 134, from which the first sawtooth
`waveform d1 is supplied, and a 90° phase shifter 136, that
`imparts a 90° phase shift to the sawtooth waveform d1, so
`as to produce a second sawtooth waveform d2 for applica
`tion to the downstream converter 200. Error amplifier 115
`compares a fraction of the output Voltage Vout1 at output
`node 145, as derived by a voltage divider 116, to which a
`feedback compensation filter 121 is coupled, with a refer
`ence voltage 118.
`The upstream buck converter 100 also includes an over
`current detector 119, which has a first input coupled to a
`node between a fixed current source 127 and an overcurrent
`setting resistor 123, coupled to the VCC supply voltage rail,
`to set the overcurrent trip threshold. A Reset MOSFET
`switch 129 is coupled to the connection of overcurrent
`setting resistor 123 and overcurrent detector 119. Applying
`a turn-on gate signal to Reset MOSFET switch reduces the
`VCC-referenced bias supplied through resistor 123, to trip
`the overcurrent detector and reset the dual stage converter.
`A second input of overcurrent detector 119 is coupled
`through a switch 135 to the phase node 125. The output of
`overcurrent detector 119 is coupled to a soft start circuit 117.
`which is coupled to VCC through a power on reset switch
`128, and is coupled to error amplifier 115 and an inhibit
`input of gate control logic circuit 110. In response to an
`overcurrent condition, which trips the overcurrent detector
`119, the output of detector 119 changes state and triggers the
`soft start circuit 117.
`Since it is coupled in cascade with the upstream converter
`100, the downstream converter 200 derives all of its supply
`current from the output (i.e., Vout1) of the upstream con
`verter, so that the overcurrent detector 119 effectively serves
`both converter stages, eliminating the need for an overcur
`rent detector in downstream converter stage 200, so that only
`the single overcurrent set resistor 123 and an associated
`terminal on the IC package are required. The cascade
`connection between converters 100 and 200 also satisfies the
`requirement that the output voltage Vout2 of the downstream
`converter not exceed the upstream output voltage Vout1, and
`provides a significant savings in chip area, cost, and com
`plexity to be realized.
`45
`The downstream buck mode converter 200 includes a pair
`of electronic power Switching devices, respectively shown
`as an upper MOSFET device 220 and a lower MOSFET
`device 230, having their drainsource paths coupled in series
`between the output node VOUT1 of the upstream buck mode
`converter 100 and GND. A phase voltage node 225 between
`FETs 220/230 is coupled through an inductor 240 to a
`capacitor 250, which is referenced to GND. The connection
`245 between inductor 240 and capacitor 250 serves as a
`downstream output node from which a second regulated DC
`55
`output voltage Vout? is derived. For the non-limiting
`example of supplying a regulated voltage to a DDR DRAM,
`output voltage Vout2 may provide a V supply Voltage to
`the DRAM.
`A gate control circuit 210 for downstream buck converter
`200 Supplies Switching control signals to gate driver circuits
`211 and 212, so as to controllably turn respective power
`MOSFET switching devices 220 and 230 on and off, in
`accordance with a PWM switching waveform produce by a
`comparator 213. Gate driver circuit 211 is coupled with an
`associated bias diode and capacitor network containing
`diode 224 and capacitor 226, and gate driver circuit 212 is
`
`6
`coupled with an associated capacitor (not shown). To pro
`duce its PWM switching waveform, comparator 213 com
`pares the signal level of the second periodic reference
`waveform d2, as Supplied by dual phase sawtooth generator
`114, with a reference voltage output by a duty cycle
`controlling error amplifier 215.
`Error amplifier 215 compares a fraction of the output
`voltage Vout? at output node 245, as derived by a voltage
`divider 216, to which a feedback compensation filter 221 is
`coupled, with a reference Voltage at a Voltage reference node
`265 at the output of a voltage reference buffer amplifier 260.
`Voltage reference buffer amplifier 260 provides a voltage
`equal to a prescribed fraction (one-half, in the present
`example) of the output voltage Vout1 produced by the
`upstream converter stage 100.
`As pointed out above, since downstream converter stage
`200 derives its input voltage from the output voltage Vout1
`produced by upstream converter stage 100, the error ampli
`fier 215 will track a prescribed fraction (e.g., one-half) of the
`upstream converters output Voltage (Vout1) throughout, and
`also after a soft start in the operation of upstream converter
`stage 100. As a consequence, the soft-start characteristics of
`the upstream DC-to-DC converter 100, as established by
`soft start circuit 117, will be effectively mirrored in down
`stream DC-to-DC converter stage 200, eliminating the need
`for a separate soft start circuit in the downstream converter
`stage 200. FIG. 3 shows that the soft start transient response
`of the output voltage Vout2 of the downstream stage effec
`tively tracks or mirrors that (Vout1) of the upstream stage.
`The input to voltage reference buffer amplifier 260 is
`coupled through a voltage divider 262 to the Voltage output
`Vout1 produced by the upstream converter stage 100. The
`output of the reference buffer amplifier 260 is further
`coupled to a (keep alive”) window regulator 270. Window
`regulator 270 is operative to produce a shutdown signal for
`the downstream converter 200, and is coupled to receive a
`Voltage proportional to the second output Voltage Vout2
`produced at output node 245, and an externally supplied
`shutdown or inhibit signal (EXT INH).
`The use of an external converter-shutdown signal pro
`vides the ability to selectively shut down the downstream
`converter stage, independently of the upstream converter
`stage. This serves to ameliorate one of the limitations of
`buckmode PWM converters —the fact that they typically
`consume a significant amount of power, even when not
`being used. Thus, one or both of DC-to-DC converters 100
`and 200 may be shut down when not in use. Whenever the
`downstream converter stage 200 is in shut down mode, it is
`preferred that its output voltage Vout? be maintained within
`a prescribed voltage window. Without this keep alive
`voltage window confinement criterion, Vout2 might drift to
`a value that would prohibit a soft start after the shut down
`is concluded, unless a separate Soft start circuit is in the
`downstream converter.
`To avoid this potential problem, window regulator 270 is
`operative to maintain the value of the output voltage Vout2
`produced by the downstream converter stage within a pre
`scribed voltage window (e.g., +/-10%) of the regulated
`output voltage Vout1 (between 0.45 Vout1 and 0.55 Vout1.
`in present example), so that no soft start delay is needed
`when the second converter is turned back on. This is possible
`since, during the shut down interval, the loading on the
`output voltage Vout2 is typically relatively light, so that a
`fairly simple, light-duty regulator may be used for window
`regulator 270. For this purpose, window regulator 270 may
`be implemented as a resistor and a linear regulator, for
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`Samsung Electronics Co., Ltd.
`Ex. 1047, p. 8
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`7
`example, although other Suitable regulators known to those
`of skill in the art may alternatively be employed.
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`US 7,023,187 B2
`
`EXAMPLE
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`An embodiment of the dual buck mode power supply of
`the invention has been implemented in an integrated circuit,
`identified as part number ISL6530 by Intersil Corporation of
`Irvine, Calif., the assignee of the present application. Details
`regarding this part may be found in an advance data sheet,
`entitled “Dual 5V Buck and Synchronous Buck Pulse-Width
`Modulator (PWM) Controller for DDRAM Memory V,
`and V, Termination', a copy of which has been Submitted
`as an Appendix.
`As will be appreciated from the foregoing description,
`shortcomings of multi DC-DC converter architectures,
`including those described above, are effectively obviated by
`a cascaded buck mode converter power Supply architecture,
`in which a downstream converter derives its input voltage
`from the upstream converter, and generates an output DC
`Voltage that is a prescribed fraction of that input voltage.
`Cascading the two buck converter stages allows the func
`tionality of control and monitoring (including soft start and
`overcurrent detection) circuitry of the upstream converter to
`also be used for the downstream converter, so as to realize
`a significant savings in chip area, cost, and complexity.
`Moreover, incorporating a relatively reduced circuit com
`plexity Voltage window regulator in the downstream con
`verter ensures that, during shutdown, the output Voltage
`produced by the downstream converter stage will be main
`tained within a prescribed window of its regulated output
`voltage, so that no soft start delay is needed when the second
`converter is turned back on.
`While we have shown and described an embodiment in
`accordance with the present invention, it is to be understood
`that the same is not limited thereto but is susceptible to
`numerous changes and modifications as known to a person
`skilled in the art. We therefore do not wish to be limited to
`the details shown and described herein, but intend to cover
`40
`all Such changes and modifications as are obvious to one of
`ordinary skill in the art.
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`What is claimed is:
`1. A dual regulated DC voltage circuit comprising:
`an upstream buck mode DC-DC converter, coupled to
`receive a power Supply Voltage at a first input and
`providing a first regulated DC output Voltage at a first
`output; and
`a downstream buck mode DC-DC converter, having a
`second input coupled in cascade with said first output
`of said upstream buck mode DC-DC converter, so that
`said downstream buck mode DC-DC converter
`receives said first regulated DC output voltage at said
`second input, and providing, at a second output, a
`55
`second regulated DC output voltage that is a fraction of
`said first regulated DC output Voltage, said downstream
`buck mode DC-DC converter including a window
`regulator that is operative, in response to receipt of a
`shutdown signal applied thereto, to shut down said
`downstream buck mode DC-DC converter indepen
`dently of the operation of said upstream buck mode
`DC-DC converter providing said first regulated DC
`output Voltage, and to maintain said second regulated
`DC output voltage within a predetermined voltage
`window of said first regulated DC output voltage
`during shutdown of said downstream buck mode DC
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`DC converter, so that no soft start delay is needed when
`said downstream buck mode DC-DC converter is
`turned back on.
`2. The dual regulated DC voltage circuit according to
`claim 1, wherein said upstream buck mode DC-DC con
`verter includes an overcurrent detector and a soft start
`circuit, which respectively provide overcurrent protection
`and soft start operation for both of said upstream and
`downstream buck mode DC-DC converters.
`3. The dual regulated DC voltage circuit according to
`claim 1, wherein said upstream buck mode DC-DC con
`verter includes a first pair of output Switching circuits
`coupled between a power Supply Voltage terminal and a
`Voltage reference terminal, and having a common node
`thereof coupled through a first output inductor to said first
`output, and a first pulse width modulation driver circuit
`coupled to control the Switching operation of said first pair
`of output Switching circuits and thereby control the genera
`tion of said first regulated DC output Voltage at a first output,
`and wherein said downstream buck mode DC-DC converter
`includes a second pair of output Switching circuits coupled
`between said first output and said Voltage reference terminal,
`and having a common node thereof coupled through a
`second output inductor to said second output, and a second
`pulse width modulation driver circuit coupled to control the
`Switching operation of said second pair of output Switching
`circuits and thereby control the generation of said second
`regulated DC output Voltage at a second output, and further
`including a dual phase Sawtooth generator for Supplying first
`and second sawtooth waveforms, shifted in phase relative to
`one another, to said first and second pulse width modulation
`driver circuits for controlling the generation of first and
`second pulse width modulation signals Supplied to said first
`an