CN1812236B

CN1812236B - Low voltage logic operation using higher voltage supply levels

Info

Publication number: CN1812236B
Application number: CN 200510114989
Authority: CN
Inventors: 塞哈特·苏塔迪嘉
Original assignee: Mawier International Trade Co Ltd
Current assignee: Kaiwei International Co; Marvell International Ltd; Marvell Asia Pte Ltd
Priority date: 2004-11-29
Filing date: 2005-11-16
Publication date: 2011-04-13
Anticipated expiration: 2025-11-16
Also published as: CN1812095B; CN1812094B; CN1812238B; CN1812238A; CN1812095A; CN1812236A; CN1812094A

Abstract

A circuit comprises 2<n> modules that are connected in series between a first and a second reference potentials. 2<n>-1 nodes that are arranged between adjacent ones of said 2<n> modules. 2<n> -1 2:1 DC/DC converters are arranged, wherein each of said 2<n> -1 2:1 DC/DC converters communicates with a respective one of said 2<n>-1 nodes.

Description

Use the low-voltage logical operation of higher voltage power supply electrical level

Technical field

The operation of the present invention relates to use the low pressure compound logic of higher voltage power supply electrical level and lower current levels grand (complex logic macro) and/or module.

Background technology

In the past during the decade, complementary metal oxide semiconductors (CMOS) (CMOS) technology has produced littler device by the transistor of integrated greater number.For example, current microprocessor is than more than powerful thousand times of making before 10 years of microprocessor.

The power consumption of microprocessor is also increasing.Now, the power consumption of some microprocessors surpasses 100W.The supply power voltage level that the modern processors that uses low voltage CMOS technology to make up adopts seldom surpasses 1v.The levels of current that need surpass as a result, 100A based on the microprocessor of CMOS.

Physical obstacle begins to limit the magnitude of current of these devices of flowing through.An obstacle relates to and the relevant voltage drop of the distribution of electric power in these microprocessors.The voltage drop that the dead resistance of 1m Ω in chip package and/or printed circuit board (PCB) (PCB) bus plane can produce 100mV.In fact, it is very difficult under the condition that does not significantly increase material and relevant treatment cost dead resistance being reduced to less than 1 M Ω.

For example, the resistance of the golden wire bonds in the general semiconductor package part has the resistance of about 100M Ω when 1 micron length 5mm of diameter.For with the general supply resistance limits below 1M Ω, each power supply connects (VDD and VSS) must be restricted to the Ω less than 0.5M.This method need surpass 400 wire bonds.Because other sources of dead resistance will need more wire bonds.

A kind of method has been removed wire bonds and has been used the Flip-Chip Using technology.This method has solved the subproblem in the packaged resistance problem.The item of other considerations comprises the metallic resistance in the semiconductor self, the metallic resistance of Flip-Chip Using part and the also necessary phase coadaptation of metallic resistance of printed circuit board (PCB) (PCB).Along with chip continues to dwindle, the trace of wiring must be done narrowlyer.As a result, must use thinner metal material, and this has increased dead resistance.

The application is the U.S. Patent application No.11/098 that submitted on April 4th, 2005,129 continuation application, this application requires the U.S. Provisional Application No.60/631 that submitted on November 29th, 2004, the U.S. Provisional Application No.60/663 that on March 21st, 552 and 2005 submitted, 933 priority.The disclosure of above-mentioned application is incorporated herein by reference.

Summary of the invention

A kind of circuit comprise first module and with second module of first module communication.First and second modules are connected in series between first and second reference potentials.Node communication between the current balance module and first and second modules, and the current drain that reduces between first and second modules is poor.

In other respects, the current balance module comprises buck converter (buck converter).Buck converter comprises the conductive switch of communicating by letter with the 3rd reference potential.Freely turning round switch (freewheelingswitch) communicates by letter with conductive switch with the 4th reference potential.Inductance element and described conductive switch and freely turn round switch and described node communication.Capacity cell and the 4th reference potential and described node communication.

In other respects, the current balance module comprises 2: 1 DC/DC converters.The DC/DC converter comprised first and second conductive switchs in 2: 1.First and second inductance elements are communicated by letter with first and second conductive switchs.First and second freely turn round switch communicates by letter with first and second conductive switchs, so that a current path to be provided during the non-conductive period.The DC/DC converter also comprised drive signal generator in 2: 1, the drive signal that is used to produce control first and second conductive switchs and freely turns round switch.First and second inductance elements are wrapped on the public core.First and second conductive switchs, first and second inductance elements and first and second freely turn round switch and connect with the buck configuration, make output voltage be approximately half of input voltage amplitude.

In other respects, the current balance module comprises equalizer switch capacitor element.Equalizer switch capacitor element comprises first capacity cell with first end and second end, and wherein first end of first capacity cell is communicated by letter with first reference potential with first module, second end of first capacity cell and described node communication.Second capacity cell have first end of communicating by letter with second reference potential with second module and with second end of described node communication.The 3rd capacity cell has first and second ends.A plurality of switches are selectively connected thereto first and second modules with first, second and the 3rd electric capacity and optionally disconnect and is connected the current drain of balanced first and second modules.Described a plurality of switch comprises first switch, second switch, the 3rd switch and the 4th switch, wherein first switch has first end of communicating by letter with first end of first capacity cell and second end of communicating by letter with first end of the 3rd capacity cell, second switch has first end of communicating by letter with first end of second capacity cell and second end of communicating by letter with second end of the 3rd capacity cell, the 3rd switch have first end of communicating by letter with first end of the 3rd capacity cell and with second end of described node communication, the 4th switch have first end of communicating by letter with second end of the 3rd capacity cell and with second end of described node communication.Drive signal generator produces the drive signal that is used for controlling described a plurality of switches.

In other respects, the current balance module comprises that linearity recommends (push-pull) adjuster.Linearity is recommended adjuster and is comprised that first and second linearities recommend adjuster.The first rank linearity recommend adjuster comprise first operational amplifier (opamp), have with the first transistor of the control input of the output communication of first operational amplifier, the first terminal of communicating by letter with the 3rd reference potential and with second terminal of described node communication.The second rank linearity recommend adjuster comprise second operational amplifier (opamp), have with the transistor seconds of the control input of the output communication of second operational amplifier, with the first terminal of described node communication and second terminal of communicating by letter with the 4th reference potential.Linearity is recommended adjuster and is also comprised the resistive element with first end and second end, first end of resistive element and first input communication of first and second operational amplifiers, second end of resistive element and described node communication.

In other respects, the current balance module comprises hysteresis comparator (hysteresis comparator) module.The hysteresis comparator module comprises at least one in adjustable bias module, BREATHABLE BANDWIDTH module and/or the adjustable delay module.Circuit is an integrated circuit.

In other respects, DC/DC converter receiving inputted signal and produce output signal.The 22: 1 DC/DC converter have with the input of the output communication of DC/DC converter and with the output of the input communication of 2: 1 DC/DC converters.

In other respects, provide third and fourth module.First, second, third and four module between first and second reference potentials, be connected in series.The current balance module comprises the one 2: 1 DC/DC converter, the first node between the one 2: 1 DC/DC converter and first reference potential, first and second modules and second and three module between Section Point communicate by letter.The 22: 1 DC/DC converter is communicated by letter with the 3rd node and second reference potential between Section Point, third and fourth module.The 32: 1 DC/DC converter is communicated by letter with first reference potential, Section Point and second reference potential.

In other respects, a kind of equipment comprises described circuit, and comprises that further N is to circuit.First module comprises that N is to the first a pair of circuit in the circuit.Second module comprises that N is to a pair of second circuit in the circuit.N comprises treatment circuit to circuit.Three module comprises that N is to another the first right circuit in the circuit.Four module comprises that N is to another the right second circuit in the circuit.Third and fourth module is connected in series between first and second reference potentials, and the node communication between the current balance module and third and fourth module.First, second, third and four module comprise signal processing module.First, second, third and four module comprise the graphics pipeline module.

In other respects, a kind of treatment system comprises described equipment.First module comprises that first CPU (CPU) and second module comprise the 2nd CPU.Operating system is communicated by letter with first and second CPU, and carries out the load balancing of first and second CPU and/or at least one in the throttling, and is poor with the current drain that reduces between first and second CPU.

In other respects, first and second CPU are realized by single integrated circuit.The current balance module comprises 2: 1 DC/DC converters with first and second inductors.Assembly in 2: 1 DC/DC converters except that first and second inductors is realized by integrated circuit.

In other respects, a kind of system comprises treatment system, and further comprise printed circuit board (PCB) (PCB), the pin that is arranged in first and second slots on the PCB and stretches out and received by first and second slots from integrated circuit.First and second inductors are attached to integrated circuit, and are disposed between integrated circuit and the PCB.

The second channel module that a kind of network equipment comprises first channel module, be connected in series with first channel module, the 3rd channel module that is connected in series with the second channel module and the 4th channel module that is connected in series with the 3rd channel module.The first and the 4th channel module is connected in series between first and second reference potentials.Be equal on the first, second, third and the 4th channel module function.

In other respects, between a kind of current balance module and first and second channel modules, between the second and the 3rd channel module and the node communication between third and fourth channel module, and the current drain that reduces between the first, second, third and the 4th channel module is poor.This network equipment is the 1000Base-T compatibility.This network equipment is the 10GBase-T compatibility.

In other respects, the current balance module comprises buck converter.The current balance module comprises 2: the 1DC/DC converter.The current balance module comprises equalizer switch capacitor element.The current balance module comprises that linearity recommends adjuster.The current balance module comprises the hysteresis comparator module.

A kind of treatment system comprises first processing module and second processing module of communicating by letter with first processing module.First and second processing modules are connected in series between first and second reference potentials.Operating system is communicated by letter with first and second processing modules, and carries out the load balancing of first and second processing modules and/or at least one in the throttling, and is poor with the current drain that reduces between first and second processing modules.

In other respects, the node communication between the current balance module and first and second processing modules, and the current drain that reduces between first and second processing modules is poor.

In other respects, the current balance module comprises buck converter.The current balance module comprises 2: the 1DC/DC converter.The current balance module comprises equalizer switch capacitor element.The current balance module comprises that linearity recommends adjuster.The current balance module comprises the hysteresis comparator module.First and second processing modules comprise the first and second graphics pipeline modules.

First and second processing modules are all realized by single integrated circuit.The current balance module comprises 2: 1 DC/DC converters with first and second inductors.Assembly in 2: 1 DC/DC converters except that first and second inductors is realized by integrated circuit.

A kind of system comprises treatment system, and further comprise printed circuit board (PCB) (PCB), the pin that is arranged in first and second slots on the PCB and stretches out and received by first and second slots from integrated circuit.First and second inductors are attached to integrated circuit, and are disposed between integrated circuit and the PCB.

A kind of circuit be included in be connected in series between first and second reference potentials 2 ⁿIndividual module.2 ⁿOne 1 nodes are set at 2 ⁿBetween the adjacent block of individual module.2 ⁿIn-1 2: 1 DC/DC converter each and 2 ⁿCorresponding communication in-1 node.

In other respects, 2 ⁿ-12: 1 DC/DC converter arrangement is in n branch road.First branch road comprises 2 ⁿIn-1 2: 1 DC/DC converter one, second branch road comprises 2 ⁿ-12: in the 1DC/DC converter two, and the n branch road comprises 2 ⁿIn-1 2: 1 DC/DC converter 2 ^N-1Individual.Module comprises that compound logic is grand.Module comprises application-specific integrated circuit (ASIC) (ASIC).Module comprises processing module.

A kind of method comprises: use first module to carry out first function; Use with second module of first module communication and carry out second function, first and second modules are connected in series between first and second reference potentials; And the current drain that reduces between first and second modules is poor.

In other respects, described method comprises and uses buck converter to carry out the described step that reduces.Described method comprises uses 2: 1 DC/DC converters to carry out the described step that reduces.Described method comprises uses equalizer switch capacitor element to carry out the described step that reduces.Described method comprises that using linearity to recommend adjustment module carries out the described step that reduces.Described method comprises uses the hysteresis comparator module to carry out the described step that reduces.

A kind of method of operational network equipment comprises first communication channel is provided; The second communication of connecting with first communication channel channel is provided; The third communication of connecting with second communication channel channel is provided; And provide the four-way of connecting to believe channel with third communication channel.First and four-way letter channel be connected in series between first and second reference potentials, and wherein first, second, third and four-way letter channel function on be equal to.

In other respects, described method comprise reduce first, second, third and the current drain of four-way letter interchannel poor.The described network equipment is the 1000Base-T compatibility.This network equipment is the 10GBase-T compatibility.

A kind of method comprises first processing module is provided; Second processing module of communicating by letter with first processing module is provided, and wherein first and second processing modules are connected in series between first and second reference potentials; And carry out the load balancing of first and second processing modules and/or at least one in the throttling, poor with the current drain that reduces between first and second processing modules.

In other respects, described method comprises that the current drain that reduces between first and second processing modules is poor.

First and second processing modules are all realized by single integrated circuit.The DC/DC converter comprised first and second inductors in 2: 1.Assembly in 2: 1 DC/DC converters except that first and second inductors is realized by integrated circuit.

First and second slots are disposed on the PCB, and pin stretches out from integrated circuit and received by first and second slots.First and second inductors be attached to integrated circuit and be disposed in integrated circuit and PCB between.

A kind of method, comprise be provided at be connected in series between first and second reference potentials 2 ⁿIndividual module; Provide and be set at 2 ⁿBetween the adjacent block of individual module 2 ⁿ-1 node; And be provided for carrying out 2 of conversion ⁿ-12: 1 DC/DC converter, wherein 2 ⁿIn-1 2: 1 DC/DC converter each and 2 ⁿCorresponding communication in-1 node.

In other respects, 2 ⁿ-12: 1 DC/DC converter arrangement is in n branch road.First branch road comprises 2 ⁿIn-1 2: 1 DC/DC converter one, second branch road comprises 2 ⁿ-12: in the 1DC/DC converter two, and the n branch road comprises 2 ⁿIn-1 2: 1 DC/DC converter 2 ^N-1Individual.2 ⁿIndividual module comprises that compound logic is grand.2 ⁿIndividual module comprises application-specific integrated circuit (ASIC) (ASIC).2 ⁿIndividual module comprises processing module.

A kind of circuit comprises first device that is used to carry out first function; And second device that is used to carry out second function and communicates by letter with first device.First and second devices are connected in series between first and second reference potentials.Node communication between the current balance device and first and second devices, and the current drain that reduces between first and second devices is poor.

In other respects, the current balance device comprises buck converter.Buck converter comprises the switch of communicating by letter with the 3rd reference potential conductive switch device.Switch is communicated by letter with the conductive switch device with the 4th reference potential with freely turning round switching device.Being used to provides the inductance device and the described conductive switch device of inductance and freely turns round switching device and described node communication.Be used to provide capacitive means and the 4th reference potential and the described node communication of electric capacity.

In other respects, the current balance device comprises that conversion was with 2: 1 DC/DC converting means.The DC/DC converting means comprised the first and second conductive switch devices that switch is used in 2: 1.Be used to provide first and second inductance devices of inductance to communicate by letter with the first and second conductive switch devices.What switch was used first and second freely turns round switching device and communicates by letter with the first and second conductive switch devices, to provide current path during the non-conductive period.The DC/DC converting means also comprised driving signal generator in 2: 1, the drive signal that is used to produce the control first and second conductive switch devices and freely turns round switching device.First and second inductance devices are wrapped on the public core.The first and second conductive switch devices, first and second inductance devices and first and second freely turn round switching device and connect with the buck configuration, make output voltage be approximately half of input voltage amplitude.

In other respects, the current balance device comprises the equalizer switch capacitive means that is used for switching capacity.The equalizer switch capacitive means comprises first capacitive means that is used to provide electric capacity with first end and second end, and wherein first end of first capacitive means is communicated by letter second end of first capacitive means and described node communication with first device with first reference potential.First end that is used to provide second capacitive means of electric capacity to have to communicate by letter with second reference potential with second device and with second end of described node communication.Be used to provide the 3rd capacitive means of electric capacity to have first and second ends.A plurality of switching devices that switch is used are selectively connected thereto first and second devices with first, second and the 3rd capacitive means and optionally disconnect and being connected, come balanced first and second current drains that install.Described a plurality of switching device comprises first switching device that switch is used, the second switch device, the 3rd switching device and the 4th switching device, wherein first switching device has first end of communicating by letter with first end of first capacitive means and second end of communicating by letter with first end of the 3rd capacitive means, the second switch device has first end of communicating by letter with first end of second capacitive means and second end of communicating by letter with second end of the 3rd capacitive means, the 3rd switching device have first end of communicating by letter with first end of the 3rd capacitive means and with second end of described node communication, the 4th switching device have first end of communicating by letter with second end of the 3rd capacitive means and with second end of described node communication.Driving signal generator produces the drive signal that is used for controlling described a plurality of switching devices.

In other respects, the current balance device comprises that the linearity of regulating usefulness recommends adjusting device.Linearity is recommended adjusting device and is comprised that first and second linearities recommend adjuster.The first rank linearity recommend adjuster comprise first operational amplifier (opamp), have with the first transistor of the control input of the output communication of first operational amplifier, the first terminal of communicating by letter with the 3rd reference potential and with second terminal of described node communication.The second rank linearity recommend adjuster comprise second operational amplifier (opamp), have with the transistor seconds of the control input of the output communication of second operational amplifier, with the first terminal of described node communication and second terminal of communicating by letter with the 4th reference potential.Linearity is recommended adjusting device and is also comprised the resistive element with first end and second end, first end of resistive element and first input communication of first and second operational amplifiers, second end of resistive element and described node communication.

In other respects, the current balance device comprises the hysteresis comparator device that is used for euqalizing current.The hysteresis comparator device comprises the adjustable bias device that is used for adjusting biasing, be used to adjust the BREATHABLE BANDWIDTH device of bandwidth and/or be used to adjust at least one of adjustable delay device of delay.

In other respects, circuit is an integrated circuit.The DC/DC converting means receiving inputted signal that conversion is used also produces output signal.The 22: the 1 DC/DC converting means that conversion is used have with the input of the output communication of DC/DC converting means and with the output of the input communication of 2: 1 DC/DC converting means.

In other respects, circuit comprises third and fourth device that is used to carry out third and fourth function.The first, second, third and the 4th device is connected in series between first and second reference potentials.The current balance device comprises the one 2: 1 DC/DC converting means, the 22: 1 DC/DC converting means and the 32: the 1 DC/DC converting means that conversion is used, and first node between the one 2: 1 DC/DC converting means and first reference potential, first and second devices and the Section Point between the second and the 3rd device are communicated by letter.The 22: 1 DC/DC converting means is communicated by letter with the 3rd node and second reference potential between Section Point, third and fourth device.The 32: 1 DC/DC converting means is communicated by letter with first reference potential, Section Point and second reference potential.

A kind of equipment comprises described circuit, and comprises that further N is to circuit.First device comprises N to the first a pair of circuit in the circuit, and second device comprises that N is to a pair of second circuit in the circuit.N comprises the processing unit of handling usefulness to circuit.The 3rd device that is used for carrying out the 3rd function comprises N another first right circuit to circuit.The 4th device that is used for carrying out the 4th function comprises N another right second circuit to circuit.Third and fourth device is connected in series between first and second reference potentials, and the node communication between the current balance device and third and fourth device.The first, second, third and the 4th device comprises the signal processing apparatus of handling usefulness.

In other respects, Graphics Processing Unit (GPU) comprises described equipment.The first, second, third and the 4th device comprises the graphics pipeline device that is used for processing graphics.

In other respects, a kind of treatment system comprises described equipment.First device comprises that first processing unit and second device of handling usefulness comprise second processing unit of handling usefulness.Operating system is communicated by letter with first and second processing unit, and carries out the load balancing of first and second processing unit and/or at least one in the throttling, and is poor with the current drain that reduces between first and second processing unit.First and second processing unit are all realized by single integrated circuit.

In other respects, the current balance device comprises that conversion with first and second inductance devices was with 2: 1 DC/DC converting means.Assembly in 2: 1 DC/DC converting means except that first and second inductance devices is realized by integrated circuit.A kind of system comprises treatment system, and further comprise printed circuit board (PCB) (PCB), the pin that is arranged in first and second slots on the PCB and stretches out and received by first and second slots from integrated circuit.First and second inductance devices are attached to integrated circuit, and are disposed between integrated circuit and the PCB.

A kind of network equipment comprise first CU channel unit that is used to provide first communication channel, with first CU channel unit be connected in series the second channel device that is used to provide the second communication channel, being connected in series to be used to provide the 3rd CU channel unit of third communication channel and to be connected in series with the 3rd CU channel unit with the second channel device is used to provide the 4th CU channel unit of four-way letter channel.The first and the 4th CU channel unit is connected in series between first and second reference potentials, and the first, second, third and the 4th CU channel unit is equal on function.

In other respects, between a kind of current balance device and first and second CU channel unit that is used for euqalizing current, between the second and the 3rd CU channel unit and the node communication between third and fourth CU channel unit, and the current drain that reduces between the first, second, third and the 4th CU channel unit is poor.This network equipment is the 1000Base-T compatibility.This network equipment is the 10GBase-T compatibility.

In other respects, the current balance device comprises buck converter.The current balance device comprises 2: 1 DC/DC converting means that conversion is used.The current balance device comprises the equalizer switch capacitive means that is used for switching capacity.The current balance device comprises that the linearity of regulating usefulness recommends adjusting device.The current balance device comprises the hysteresis comparator device that is used for euqalizing current.The hysteresis comparator device comprises the adjustable bias device that is used for adjusting biasing, be used to adjust the BREATHABLE BANDWIDTH device of bandwidth and/or be used to adjust at least one of adjustable delay device of delay.

A kind of treatment system comprises first processing unit of handling usefulness and processing second processing unit of communicating by letter with first processing unit.First and second processing unit are connected in series between first and second reference potentials.Be used to provide the operating means of operating system to communicate by letter, and carry out the load balancing of first and second processing unit and/or at least one in the throttling with first and second processing unit, poor with the current drain that reduces between first and second processing unit.

In other respects, the node communication between the current balance device and first and second processing unit, and the current drain that reduces between first and second processing unit is poor.

In other respects, the current balance device comprises buck converter.The current balance device comprises 2: 1 DC/DC converting means that conversion is used.The current balance device comprises the equalizer switch capacitive means that is used for switching capacity.The current balance device comprises that the linearity of regulating usefulness recommends adjusting device.The current balance device comprises the hysteresis comparator device that is used for euqalizing current.The hysteresis comparator device comprises the adjustable bias device that is used for adjusting biasing, be used to adjust the BREATHABLE BANDWIDTH device of bandwidth and/or be used to adjust at least one of adjustable delay device of delay.Processing unit comprises the graphics pipeline device that is used for processing graphics.

First and second processing unit are all realized by single integrated circuit.The current balance device comprises that conversion with first and second inductance devices that are used to provide inductance was with 2: 1 DC/DC converting means.Assembly in 2: 1 DC/DC converting means except that first and second inductance devices is realized by integrated circuit.

A kind of circuit comprises: be connected in series between first and second reference potentials and be used for carrying out respectively 2 ⁿ2 of individual function ⁿIndividual device is set at 2 ⁿBetween the neighboring devices of individual device 2 ⁿ-1 node, and conversion use 2 ⁿ-12: 1 DC/DC converting means.2 ⁿIn-1 2: 1 DC/DC converting means each and 2 ⁿCorresponding communication in-1 node.

In other respects, 2 ⁿ-12: 1 DC/DC converting means is arranged in n the branch road.First branch road comprises 2 ⁿIn-1 2: 1 DC/DC converting means one, second branch road comprises 2 ⁿIn-1 2: 1 DC/DC converting means two, and the n branch road comprises 2 ⁿIn-1 2: 1 DC/DC converting means 2 ^N-1Individual.2 ⁿIndividual device comprises that compound logic is grand, application-specific integrated circuit (ASIC) (ASIC) and/or handle the processing unit of usefulness.

By detailed description hereinafter, the applicable other field of the present invention will become clear.Should be appreciated that to be used to illustrate that the detailed description of the preferred embodiment for the present invention and specific embodiment are only used for illustrational purpose, rather than want to limit the scope of the invention.

Description of drawings

To more fully understand the present invention by detailed explanation and accompanying drawing, wherein:

Figure 1A and Figure 1B are the functional block diagrams that shows grand with the compound logic that piles up of two times of normal voltage level and half normal levels work in module respectively;

Fig. 2 A and Fig. 2 B are the functional block diagrams that shows the grand and module of the compound logic that piles up with current balance module respectively;

Fig. 3 A and Fig. 3 B show the functional block diagram that is carried out the grand and module of the balanced compound logic that piles up by buck converter;

Fig. 4 A and Fig. 4 B show the functional block diagram that is carried out the grand and module of the balanced compound logic that piles up by 2: 1 DC/DC converters;

Fig. 5 A and Fig. 5 B show the functional block diagram that is carried out the grand and module of the balanced compound logic that piles up by the first exemplary equalizer switch capacitor element;

Fig. 6 A and Fig. 6 B show the functional block diagram that is carried out the grand and module of the balanced compound logic that piles up by the second exemplary equalizer switch capacitor element;

Fig. 7 A and Fig. 7 B show by linearity and recommend the functional block diagram that adjuster carries out the grand and module of the balanced compound logic that piles up;

Fig. 8 A and Fig. 8 B show the functional block diagram that is carried out the grand and module of the balanced compound logic that piles up by hysteresis comparator;

Fig. 9 A shows according to prior art and uses DC/DC converter and 2: the 1 converters functional block diagram to module or grand supply voltage and current;

Fig. 9 B shows the functional block diagram of implementations more according to the present invention to two modules of piling up or grand supply voltage and current;

Fig. 9 C shows the functional block diagram of the implementation other according to the present invention to four modules of piling up or grand supply voltage and current;

Figure 10 A shows the functional block diagram of the communication equipment that comprises a plurality of communication channels, and wherein each communication channel has a signal processor;

Figure 10 B shows the functional block diagram to the communication equipment supply voltage and current of Figure 10 A;

Figure 11 A shows the functional block diagram of the Graphics Processing Unit (GPU) that comprises a plurality of graphics pipeline modules;

Figure 11 B shows the functional block diagram to the connection of the graphics pipeline module supply voltage and current of Figure 11 A;

Figure 12 shows the functional block diagram of first and second processors, power regulation module and optional current balance module, wherein the current drain of balanced first and second processing of power regulation module;

Figure 13 A shows first and second processors, frequency equilibrium module and optional 2: the functional block diagram of 1DC/DC converter, and wherein the frequency equilibrium module reduces poor between the operating frequency of first and second processors, to reduce the unbalanced of electric current;

Figure 13 B shows the functional block diagram of the exemplary layout of first and second processors on the semiconductor element and 2: 1 DC/DC converters;

Figure 13 C shows the packaging part of semiconductor element of Figure 13 B and the end view of the external inductance on the PCB; And

Figure 14 shows the functional block diagram of first and second processors, operating system and optional current balance module, wherein the current drain of balanced first and second processors of operating system.Embodiment

Explanation to (one or more) preferred embodiment only is exemplary below, is not to limit the present invention and application or use.For the sake of clarity, will use identical label to identify similar element in the accompanying drawing.As used herein, the processor (share, special-purpose or group) that term module refers to application-specific integrated circuit (ASIC) (ASIC), electronic circuit, the one or more softwares of execution or firmware program and memory, microprocessor subsystem, combinational logic circuit, compound logic is grand and/or other suitable assemblies of described function are provided.

With reference to Figure 1A and Figure 1B, the present invention self piles up to overcome actual dead resistance obstacle many group devices (for example compound logic is grand and/or module).In Figure 1A, compound logic grand 20 and 24 self piles up and is connected V _DDAnd V _LBetween.In some implementations, V _LCan be ground.In Figure 1B,

module

30 and 34 self is piled up and is connected V _DDAnd V _LBetween.If compound logic grand 20 and 24 or the multiplicity of

module

30 and 34 by approximate two equal portions that are divided into, and if this two halves approximately equal ground operation, then the electric current demand is approximately non-half of device of piling up.

The working voltage of the device that piles up is non-twice of piling up device.Yet, can not guarantee compound logic grand 20 and 24 or

module

30 and 34 both will consume essentially identical levels of current.This seemingly may solve hardly between the topic, unless can make two halves absorb the essentially identical magnitude of current.The voltage drop of in fact having no idea to guarantee this two halves is to be applied to half of total voltage on the entire device.

With reference now to Fig. 2 A and Fig. 2 B,, current balance module 50 according to the present invention is connected to V _DD, V _LAnd/or

logic macro

20 and 24 or

module

30 and 34 between node 52 at least one.Current balance module 50 is attempted stable market supply to

logic macro

20 and 24 or the magnitude of current of module 30 and 34.Particularly, current balance module 50 is with (V _DD-V _L) approximate 1/2 compound logic grand 20 and 24 that is fed among Fig. 2 A in each or Fig. 2 B in

module

30 and 34 in each.Exemplary current balance module 50 comprises that buck converter, 2: 1 DC/DC converters, linearities recommend adjuster, low pressure drop (low drop-out, LDO) adjuster, equalizer switch capacitor element, switched inductors device, capacitive/inductive device, hysteresis comparator and/or other similar devices, this will further describe hereinafter.

With reference to figure 3A and Fig. 3 B, the grand or module of the shown compound logic that piles up is carried out equilibrium by buck converter 68.Buck converter 68 can have the topological structure shown in Fig. 3 A and the 3B and/or any other suitable topological structure.Buck converter 68 comprises conductive switch 70 and freely turns round switch 72.Control module 73 produces the drive signal that is used for switch 70 and 72.Control module 73 can sense node 52 places voltage and/or electric current, and come control switch based on this.In some implementations, switch 70 and 72 has inverse state.One end of inductance element 78 is connected between switch 70 and 72, the other end be connected compound logic grand 20 and 24 or

module

30 and 34 between.Buck converter 68 absorbs or sends electric current to provide balanced.

With reference now to Fig. 4 A and Fig. 4 B,, show a kind of implementation, thereby be used for making the voltage approximately equal of seeing on this two halves at euqalizing current between the two halves.In Fig. 4 A, balanced action is to have passed through to utilize 2: 1 DC/DC converters 100 of coupling inductor 104 to finish.The U.S. Patent application No.10/693 that further details of operation was submitted on October 24th, 2003 sets forth among 787 " the Voltage Regulator ", and this patent application is incorporated into this by reference in full.

2: 1 DC/DC converters 100 comprise two buck converters with the phase difference work of 180 degree, with from input voltage V _DDProduce output voltage V _OUTEach buck converter comprises

conductive switch

110a or 110b, freely turns

round switch

114a or 114b and inductor 104a or 104b.Output capacitance 118 is carried out filtering to the output voltage of each buck converter.Owing to have negligible ripple current, so the value of output capacitance 118 can be reduced.In addition and since the input and output of 2: 1 DC/DC converters 100 between close-coupled, any electric capacity of input all with output capacitance 118 collaborative works, so that the shunt capacitance of output place load effectively to be provided.Control module 119 produces the drive signal that is used for

switch

110a, 110b, 114a and 114b.Control module 119 can sense node 52 places voltage or electric current, and come control switch based on this.

Start-up circuit 130 optionally is provided, and is maintained at less than V between the starting period to guarantee node 52 _DDThe voltage place.In some implementations, node is maintained at approximate V between the starting period _DD/ 2.In some implementations, start-up circuit 130 comprises one or more capacitors.Perhaps, V _DDCan increase between the starting period or the slope on rise and prevent the overvoltage at module two ends, and guarantee that node 52 is in and be maintained at approximate V between the starting period _DD/ 2 and/or less than threshold voltage V _TH(threshold voltage V _THLess than V _DD) at least a situation.Threshold value V _THShould be less than the voltage that will cause grand and/or module damage.

In Fig. 4 B, the output capacitance 118 of Fig. 4 A is marked as 118B.Can add another electric capacity 118A alternatively to guarantee grand and/or module receives and is no more than V between the starting period _THAnd/or approximate V _DD/ 2 voltage.Perhaps, V _DDCan on increase or slope between the starting period, rise and prevent overvoltage grand and/or the module two ends.Can also use the method for other deboosts between the starting period.In some implementations, the capacitance of electric capacity is set to equal substantially.

In some implementations,

inductor

104a and 104b can close-coupled be in the same place, and have and be approximately 1 coupling

coefficient K.Inductor

104a and 104b can be wrapped in the electrical inductor assembly 104 that the high coupling coefficient between inductor 104a and the 104b is provided with formation on the shared magnetic core.Select the polarity of inductor winding, the DC electric current of feasible flow through

inductor

104a and 104b is approximate offsets the magnetic core of electrical inductor assembly 104 thereby the DC electric current of approximate zero is flowed through.Therefore,

inductor

104a and 104b can use the core of the reduced size of being made by low magnetic permeability material, make the littler and cost of the size (volume) of electrical inductor assembly 104 reduce.In addition, consider the transient load electric current, the transient response of 2: 1 DC/DC converters 100 is owing to the counteracting of each inductance is improved.

Any overcurrent, no matter be from or enter the compound logic that piles up grand 20 and 24 or the node 52 of

module

30 and 34, all will be absorbed back main power source with approximate 95% efficient by 2: 1 DC/DC converters 100.After startup, 2: 1 DC/DC converters 100 guarantee compound logics grand 20 and 24 or the two halves of

module

30 and 34 on the voltage approximately equal seen.Suppose that this two halves has the highest 25% mismatch aspect levels of current, then 2: 1 DC/DC converters 100 need to absorb or send entire device half electric current 25%, perhaps 1/8 of whole electric current.

With reference to the initial current demand is the microprocessor example of 100A, and 2: 1DC/DC converter 100 need absorb or send the electric current less than 12.5A.This can easily utilize integrated power MOSFET in the microprocessor die and single 1: 1 coupling inductor 104 that is installed under the microprocessor package part to realize, as Figure 13 A～13C that describes below is shown.

The U.S. Patent application No.10/810 that submits on March 26th, 2004, the U.S. Patent application No.10/693 that 452 " VoltageRegulator ", on October 24th, 2003 submit, the U.S. Patent application No.10/754 that 787 " Voltage Regulator " and on January 8th, 2004 submit, shown in 187 " the Digital Low Dropout Regulator " and buck converter and 2: 1 converter topology structures that other are suitable be described, they are incorporated into this by reference in full.

With reference now to Fig. 5 A and Fig. 5 B,, compound logic grand 20 and 24 or the stacked structure of

module

30 and 34 not only useful for high power semiconductor device, and for purpose is the low-power integrated-circuit of use in the hand-held market (for example PDA(Personal Digital Assistant), MP3 player, portable satellite broadcasting, cell phone etc.), also be useful.In many handheld application, can use a limited number of DC/DC converter to produce the required different low voltage power supply level of operation modem semi-conductor devices.

Compound logic is grand or module can under low pressure be worked and combination stacked voltage can be used for moving the application of the simulation part of integrated circuit for two, the compound logic that piles up grand 20 and 24 or

module

30 and 34 be suitable for.For example, the device with 1.8V simulation power supply can be used for the two halves of the embedded logic that moves under 0.9V is powered.Current difference between the two halves still needs to solve.

In this case, equalizer switch capacitor element 150 can be used between two halves back and forth switching current, and is shown as Fig. 5 A and Fig. 5 B.The electric current and/or the voltage at control module 154 sense node 164 places, and control

switch

158 and 160 are to change capacitor C ₁And C ₂Discharge and recharge.Equalizing capacitor C ₁And C ₂Reciprocating action can be used for guaranteeing the voltage approximately equal of two halves, even when between two halves, having electric current demand unbalanced.In some implementations, C ₁Capacitance be set to equal substantially C ₂Capacitance, to prevent between the starting period overvoltage at

module

20 and 24 two ends.In other words, between the starting period, node 164 is held less than V _THAnd/or be approximately equal to V _DD/ 2.Although show equalizer switch capacitor element, those skilled in the art will recognize that, also can use switched inductors device and/or switching capacity/inductance component.

With reference now to Fig. 6 A and Fig. 6 B,, the another kind of equalizer switch capacitor element that illustrates comprises capacitor C ₁, C ₂And C ₃, switch 180,182,184 and 186.Switched capacitor module 190 control switchs 180～186 are to absorb from the electric current of node 192 or to send electric current to node 192.In some implementations,

switch

180 and 184 is as a pair of and by switch, and switch 182 and 186 is also as a pair of and by switch, and they have opposite state.Switching capacity module 190 can sense node 192 places curtage, and come control switch based on this.Equalizing capacitor C ₁, C ₂And C ₃Reciprocating action can be used for guaranteeing the voltage approximately equal of two halves, even when between two halves, existing the electric current demand unbalanced.

With reference now to Fig. 7 A and Fig. 7 B,, under the condition of some efficient of forfeiture, can use linearity to recommend adjuster 200.If two halves is designed to relative equilibrium, then Sang Shi efficient should be minimum.This method is significantly better than linear regulator, and linear regulator generally only has 50% efficient.However, also can use linear regulator in some implementations.

Linearity is recommended adjuster 200 and is comprised first and second

operational amplifiers

204 and 208, and operational amplifier 204 is communicated by letter with the control terminal of transistor T 1 and T2 respectively with 208 output.In some implementations, transistor T 1 and T2 are the CMOS transistors.The first terminal of transistor T 1 is coupled to V _DDSecond terminal of transistor T 1 is coupled to the first terminal of transistor T 2.Second terminal of transistor T 2 is coupled to V _LHigher voltage thresholds V is coupled in the anti-phase input of operational amplifier 204 _UL, and low voltage threshold value V is coupled in the anti-phase input of operational amplifier 208 _LLThe positive input of operational amplifier 204 and an end of resistance R are coupled in the positive input of operational amplifier 208.The other end of resistance R is coupled to second and the first terminal of first and second transistor Ts 1 and T2 respectively.Second and the first terminal of first and second transistor Ts 1 and T2 also is coupled to node 210 between first and

second logic macros

20 and 24 among Fig. 7 A or the node 210 between first and

second modules

30 and 34 among Fig. 7 B respectively.

When node 210 compares target voltage Little first threshold The time, the voltage that top logic macro or module descend is too much.Top operational amplifier 204 of short duration turn-on transistor T1, transistor T 1 is with V _DDBe applied to node 210.The V at node 210 places _DDDraw high the voltage at logic macro or

module

24 or 34 two ends, and reduced the voltage at logic macro or

module

20 or 30 two ends.Work as V _DDWhen being applied to node 210, operational amplifier 204 turn-offs T1, and process is repeated until that difference is less than first threshold.

When node 210 compares target voltage Big second threshold value The time, the voltage that following logic macro or module descend is too much.Following operational amplifier 208 of short duration turn-on transistor T2, transistor T 2 is with V _LBe applied to node 210.The V at node 210 places _LDraw high the voltage at logic macro or

module

20 or 30 two ends, and reduced the voltage at logic macro or

module

24 or 34 two ends.Work as V _LWhen being applied to node 210, operational amplifier 208 turn-offs T2, and process is repeated until that difference is less than first threshold.

Can recognize, can use the adjuster of any kind.Except above-described implementation, can use other types the DC/DC converter, recommend adjuster and switching capacity device.Can also use the adjuster of other types, include but not limited to hysteresis comparator.For example, suitable hysteresis comparator comprises the U.S. Patent application No.10/602 that on June 23rd, 2003 submitted, those hysteresis comparators that also illustrate shown in 997 " the Simplified Comparator with Digitally Controllable Hysteresis andBandwidth ", it is incorporated into this by reference in full.

In Fig. 7 B, first and second capacitor C are provided ₁And C ₂With the voltage limit at module between the starting

period

30 and 34 two ends is less than V _THAnd/or be approximately equal to V _DD/ 2.In some implementations, capacitor C ₁Capacitance equal C substantially ₂Capacitance.In other words, node 210 is maintained at approximate V between the starting period _DD/ 2.

With reference now to Fig. 8 A and 8B,,

hysteresis comparator

250 and 254 is used for adjusting

logic macro

20 and 24 or the voltage at

module

30 and 34 two ends.Comparator 250 receives V _DD, higher voltage thresholds V _ULAnd the voltage at node 210 places.In some implementations, comparator 250 has fixing or adjustable bias 256, bandwidth 258 and/or postpone 260.If adjustable, then comparator 254 receives the one or more corresponding input that is used to adjust accordingly.Comparator 254 receives V _L, low voltage threshold value V _LLAnd the voltage at node 210 places.

When node 210 compares target voltage

Little higher thresholds

The time, the voltage that top logic macro or module descend is too much.Comparator 250 is with V _DDBe applied to node 210.The V at node 210 places _DDDraw high the voltage at logic macro or

module

24 or 34 two ends, and reduced the voltage at logic macro or

module

20 or 30 two ends.Work as V _DDBe applied to 210 1 of nodes and postpone after the period, comparator 250 stops V _DDBe applied to node 210.Process is repeated until that difference is less than higher thresholds.

When node 210 compares target voltage

Big low threshold value

The time, the voltage that following logic macro or module descend is too much.Comparator 254 is with V _LBe applied to node 210.The V at node 210 places _LDraw high the voltage at logic macro or

module

20 or 30 two ends, and reduced the voltage at logic macro or

module

24 or 34 two ends.Work as V _LBe applied to 210 1 of nodes and postpone after the period, comparator 254 stops V _LBe applied to node 210.Process is repeated until that difference is less than low threshold value.

In addition, those skilled in the art will recognize that,, also can use inferior the piling up of other grades although show the logic macro of two-stage and piling up of module.Can also use other equalization methods.

With reference now to Fig. 9 A,, DC/DC converter 300 receiving inputted signals also produce 4V and the output of 25A.The one 2:1 converter 304 is transformed to the input of 4V, 25A the output of 2V, 50A.The 2nd 2:1 converter 308 is transformed to the input of 2V, 50A the output of 1V, 100A.Grand or the module 312 of encapsulation can be connected to the output of 2:1 converter 308 via resistance 310 (dead resistance that on behalf of trace, it can be connected with other) on printed circuit board (PCB) (PCB) 314.Can recognize that the loss that is produced by dead resistance 310 equals I ²R, wherein I is the electric current of dead resistance R of flowing through.With reference now to Fig. 9 B,,, as mentioned above,, loss can be reduced 4 times by between a pair of grand or module of 324 and 328 places sign, connecting 2:1 converter 320 (or other current balance modules) according to the present invention.

With reference now to Fig. 9 C,, other module can connect other 2:1 converter.In Fig. 9 C, four modules or grand 340,342,344 and 346 are connected in series, and have node 347,348 and 349 in the middle of their.The one 2:1 converter 330 is connected to the output, module or grand 340 and node 348 of DC/DC converter 300.Node 348 is also connected to 2:1

converter

334 and 336 and module or grand 342 and 344.2:1 converter 334 is also connected to the output, module or grand 340 and

node

347 and 348 of DC/DC converter 300, as shown in the figure.2:1 converter 336 is also connected to

node

348 and 349, as shown in the figure.The 2:1 converter 320 of Fig. 9 B can be less than the 2:1 converter 308 of Fig. 9 A, and 2:1 converter 308 is handled all and flowed to the electric current of PCB.On the contrary, 2:1 converter 320 only needs to handle the current mismatch of piling up between the device.

More usually, comprise 2 when circuit ⁿIndividual module or when grand, it will comprise 2 ⁿ-1 2:1DC/DC converter.The 2:1DC/DC converter can be with the arranged in form of n branch road.2 ⁿ-1 2:1DC/DC converter has 2 between contiguous DC/DC converter ⁿ-1 node.2 ⁿIn-1 2:1DC/DC converter each is connected to 2 ⁿCorresponding one of-1 node.

For example in Fig. 9 C, two

branch roads

350 and 352 are arranged.First branch road 350 comprises a 2:1 converter and second branch road comprises two 2:1DC/DC converters.More usually, first branch road comprises 2 ⁰=1 2:1DC/DC converter, second branch road comprises 2 ¹=2 2:1DC/DC converters, the 3rd branch road comprises 2 ²=4 2:1DC/DC converters ..., and the n branch road comprises 2 ^N-1Individual 2:1DC/DC converter.

With reference now to Figure 10 A and Figure 10 B,, generally include a plurality of communication channel 364-1,364-2,364-3 and 364-4 (being referred to as channel 364) such as the communication equipment 360 of router, switch or other network equipments.Although only show four signal processor module, can use extra signal processor right.Each channel 364 comprises signal processor 366-1,366-2,366-3 and 366-4 (being referred to as signal processor 366).Because each in the signal processor 366 has identical design usually, so signal processor module 366 trends towards sucking the approximately uniform magnitude of current during operation.Current balance module 370 (as mentioned or hereinafter described) can be provided and be used for the difference that euqalizing current consumes.Because the mismatch degree will be very low,, can certainly use other current balance module so can use inefficient device (for example linear ldo regulator).For example, communication channel can compatible 1000Base-T ethernet standard, 10Gbase-T ethernet standard or other current or following ethernet standards or other standards.

With reference now to Figure 11 A and Figure 11 B,, Graphics Processing Unit (GPU) 380 comprise a plurality of graphics pipeline module 382-1,382-2 ... and 382-N (being referred to as graphics pipeline module 382).Because each in the graphics pipeline module 382 has identical design, so graphics pipeline module 382 trends towards sucking the identical magnitude of current during operation.Current balance module 390 (as mentioned or hereinafter described) can be provided and be used for the difference that euqalizing current consumes.

With reference now to Figure 12,, first and second processors 400 are communicated by letter with power regulation module 404 with 402, power regulation module 404 balanced first and

second processors

400 and 402 current drain.In some implementations, power regulation module 404 be based on hardware, based on software and/or based on hardware and software.In some implementations, the relative operating frequency of power regulation module 404 adjustment first and second processors is attempted euqalizing current consumption.Power regulation module 404 can also use the load balancing of first and

second processors

400 and 402 and/or throttling to attempt euqalizing current consumption.In some implementations, power regulation module 404 is used in combination with optional current balance module 406, as mentioned and hereinafter described like that.In other words, power regulation module 404 is carried out thick equilibriums and the current balance module is carried out meticulous current balance.

With reference now to Figure 13 A, Figure 13 B and Figure 13 C,, power management module 404 comprise frequency equilibrium module 404 '.Optional 2: 1DC/DC converter 406 ' also can be used to euqalizing current consumption further.In Figure 13 B, 2: 1DC/DC converter 406 ' and the exemplary layout of first and

second processors

400 and 402 be shown as and be manufactured on the semiconductor element 408.In Figure 13 C, the semiconductor element 408 of Figure 13 B is connected to PCB 412 by first and

second slots

414 and 416 that are arranged on the PCB 412.In certain embodiments, above-described with 2: the

inductor

420 and 422 of 1DC/DC converter 406 ' be associated is disposed between semiconductor element 408 and the PCB 412.Pin 426 stretches out and is received by

slot

414 and 416 from tube core 408.Although the power management module that illustrates 404 comprise frequency equilibrium module 404 ', those skilled in the art will recognize that, can with above and/or any mode described below carry out the hardware and/or the software equilibrium of electric current.

With reference now to Figure 14,, power regulation module 404 comprises operating system 404 ".OS 404, and " or chip can carry out load balancing for first and

second processors

400 and 402 by distributing thread." or chip can carry out throttling to first and/or

second processor

400 and 402 to OS404, makes that the current unevenness weighing apparatus is very little.For example, CPU speed can followingly be provided with:

Figure DEST_PATH_G051B4989X20080313D000031

1/2 each CPU of operation with peak frequency is more efficient, because each CPU can be with lower voltage operation.In some implementations, one operating frequency among the CPU is lowered and/or is increased, with the current drain of balanced other CPU.Perhaps, can at least one CPU, carry out do-nothing operation (dummy operation), with equilibrium otherwise with the current unevenness weighing apparatus that takes place.

Again with reference to figure 4A, Fig. 4 B, Fig. 5 A and Fig. 7 B, circuit and/or capacitor are used to guarantee that the voltages at nodes between grand and/or the module remains on V between the starting period _THUnder and/or be in approximate V _DD/ 2.Those skilled in the art will recognize that other implementations that illustrate and illustrate also can comprise and be used between the starting period node between grand and/or the module being maintained V here _THUnder and/or at approximate V _DDThe circuit at/2 places and/or capacitor.

Those skilled in the art can recognize from above stated specification that now broad teachings of the present invention can realize in a variety of forms.Therefore, although combine specific embodiment the present invention is described, but true scope of the present invention should not limited by them, because after having studied accompanying drawing, specification and claim, other modification will become apparent for those of ordinary skills.

Claims

1. circuit with 2: 1 DC/DC converters that are used for the euqalizing current amount comprises:

Be connected in series in 2 between first and second reference potentials ⁿIndividual module;

Be arranged on described 2 ⁿAmong the individual module between the adjacent block 2 ⁿ-1 node; And

Be used for stable market supply and give described 2 ⁿ2 of the magnitude of current of individual module ⁿ-12: 1 DC/DC converter, wherein said 2 ⁿIn-1 2: 1 DC/DC converter each is all with described 2 ⁿA corresponding node communication in-1 node, n be more than or equal to 2, and wherein said 2 ⁿ-12: 1 DC/DC converter arrangement is in n branch road, and first branch road in the wherein said n branch road comprises described 2 ⁿIn-1 2: 1 DC/DC converter one, second branch road in the described n branch road comprises described 2 ⁿTwo 2: 1 DC/DC converters in-1 2: 1 DC/DC converter, described 2 ⁿ-12: described two 2: the 1 DC/DC converters in the 1DC/DC converter are connected in series, and the n branch road in the described n branch road comprises described 2 ⁿIn-1 2: 1 DC/DC converter 2 ^N-1Individual 2: 1DC/DC converter, described 2 ⁿIn-1 2: 1 DC/DC converter described 2 ^N-1Individual 2: the 1DC/DC converter is connected in series.

2. circuit as claimed in claim 1, wherein said module comprise that compound logic is grand.

3. circuit as claimed in claim 1, wherein said module comprises application-specific integrated circuit (ASIC).

4. circuit as claimed in claim 1, wherein said module comprises signal processing module.

5. method that the circuit with 2: 1 DC/DC converters is provided comprises:

Provide and be connected in series in 2 between first and second reference potentials ⁿIndividual module;

Provide and be set at described 2 ⁿAmong the individual module between the adjacent block 2 ⁿ-1 node; And

Be provided for carrying out 2 of conversion ⁿ-12: 1 DC/DC converter, wherein said 2 ⁿIn-1 2: 1 DC/DC converter each is all with described 2 ⁿA corresponding node communication in-1 node, n be more than or equal to 2, and wherein said 2 ⁿ-12: 1 DC/DC converter arrangement is in n branch road, and first branch road in the wherein said n branch road comprises described 2 ⁿIn-1 2: 1 DC/DC converter one, second branch road in the described n branch road comprises described 2 ⁿTwo 2: 1 DC/DC converters in-1 2: 1 DC/DC converter, described 2 ⁿDescribed two 2: 1 DC/DC converters in-1 2: 1 DC/DC converter are connected in series, and the n branch road in the described n branch road comprises described 2 ⁿIn-1 2: 1 DC/DC converter 2 ^N-1Individual 2: 1 DC/DC converters, described 2 ⁿIn-1 2: 1 DC/DC converter described 2 ^N-1The DC/DC converter was connected in series in individual 2: 1.

6. method as claimed in claim 5, wherein said 2 ⁿIndividual module comprises that compound logic is grand.

7. method as claimed in claim 5, wherein said 2 ⁿIndividual module comprises application-specific integrated circuit (ASIC).

8. method as claimed in claim 5, wherein said 2 ⁿIndividual module comprises signal processing module.