Control of conversion ratios of a power source block and a bidirectional active filter

US 9,716,433 B2
Filed: 11/14/2015
Issued: 07/25/2017
Est. Priority Date: 01/15/2015
Status: Active Grant

First Claim

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1. A voltage regulator comprisinga power source block configured to convert an input voltage to an output voltage to supply current to an output load;

a storage capacitor;

an active filter configured to bi-directionally transfer energy between the output load and the storage capacitor;

wherein a conversion ratio of the active filter is controlled based on the output voltage;

wherein a conversion ratio of the power source block is at least partially controlled by a parameter related to a voltage on the storage capacitor; and

wherein when a load transient is encountered, the storage capacitor voltage falls to a reduced level, and remains at the reduced level until an end of the load transient.

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Abstract

Methods, systems and apparatuses for voltage regulation are disclosed. For an embodiment, a voltage regulator includes a power source block configured to convert an input voltage to an output voltage to supply current to an output load, a storage capacitor, and an active filter configured to transfer energy between the output load and the storage capacitor. A conversion ratio of the active filter is controlled by a parameter related to the output voltage, and a conversion ratio of the power source block is at least partially controlled by a parameter related to the voltage on the storage capacitor.

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18 Claims

1. A voltage regulator comprisinga power source block configured to convert an input voltage to an output voltage to supply current to an output load;
- a storage capacitor;
  
  an active filter configured to bi-directionally transfer energy between the output load and the storage capacitor;
  
  wherein a conversion ratio of the active filter is controlled based on the output voltage;
  
  wherein a conversion ratio of the power source block is at least partially controlled by a parameter related to a voltage on the storage capacitor; and
  
  wherein when a load transient is encountered, the storage capacitor voltage falls to a reduced level, and remains at the reduced level until an end of the load transient.
- View Dependent Claims (2, 3, 4, 5)
- - 2. The voltage regulator of claim 1, wherein the power source block comprises:
    - a series switch element;
      
      a shunt switch element;
      
      a switching controller, the switching controller operative to control opening and closing of the series switch element and the shunt switch element, wherein the opening and closing of the series switch element and the shunt switch element generates a switching voltage, and wherein filtering the switching voltage with an output inductor and a load capacitor generates the output voltage; and
      
      wherein control of the conversion ratio of the power source block comprises control of the duty cycle of the opening and closing of the series switch element and the shunt switch element, and wherein the duty cycle is controlled by the parameter related to the voltage on the storage capacitor.
  - 3. The voltage regulator of claim 2, wherein the power source block comprises a current sensor, the current sensor operative to sense an output current of the power source block;
    - and wherein the duty cycle is controlled with a signal proportional to the sensed output current combined with a signal that is proportional to the voltage on the storage capacitor.
  - 4. The voltage regulator of claim 3, wherein the switching controller comprises a power source compensation network that includes an error amplifier;
    - andwherein a signal from the current source is injected directly to an input of the error amplifier.
  - 5. The voltage regulator of claim 1, wherein the power source block comprises a current sensor, the current sensor operative to sense an output current of the power source block, wherein the conversion ratio of the power source block is additionally controlled by a value of the sensed output current.

6. A voltage regulator comprisinga power source block configured to convert an input voltage to an output voltage to supply current to an output load;
- a storage capacitor;
  
  an active filter configured to bi-directionally transfer energy between the output load and the storage capacitor;
  
  wherein a conversion ratio of the active filter is controlled based on the output voltage; and
  
  wherein a conversion ratio of the power source block is at least partially controlled by a parameter related to a voltage on the storage capacitor;
  
  wherein the power source block comprises;
  
  a series switch element;
  
  a shunt switch element;
  
  a switching controller, the switching controller operative to control opening and closing of the series switch element and the shunt switch element, wherein the opening and closing of the series switch element and the shunt switch element generates a switching voltage, and wherein filtering the switching voltage with an output inductor and a load capacitor generates the output voltage;
  
  wherein control of the conversion ratio of the power source block comprises control of the duty cycle of the opening and closing of the series switch element and the shunt switch element, and wherein the duty cycle is controlled by the parameter related to the voltage on the storage capacitor; and
  
  wherein the power source block comprises a plurality of phases of switched converters, and wherein a phase of each switched converter is offset in time to minimize a variation in a sum of output currents of the plurality of phases of switched converters.
- View Dependent Claims (7)
- - 7. The voltage regulator of claim 6, further comprising:
    - a current sensor operative to sense an average output current over phases of the plurality of phases of switched converters of the power source block, wherein the conversion ratio of the power source block is additionally controlled by a value of the sensed averaged output current.

8. A voltage regulator comprisinga power source block configured to convert an input voltage to an output voltage to supply current to an output load;
- a storage capacitor;
  
  an active filter configured to bi-directionally transfer energy between the output load and the storage capacitor;
  
  wherein a conversion ratio of the active filter is controlled based on the output voltage;
  
  wherein a conversion ratio of the power source block is at least partially controlled by a parameter related to a voltage on the storage capacitor;
  
  wherein the conversion ratio of the power source block is at least partially controlled by the parameter related to the voltage on the storage capacitor during a first mode of the voltage regulator, and the conversion ratio of the power source block is not controlled by the parameter related to the voltage on the storage capacitor during a second mode of the voltage regulator, and the voltage regulator is operative to change between the first mode and the second mode.

9. A voltage regulator comprisinga power source block configured to convert an input voltage to an output voltage to supply current to an output load;
- a storage capacitor;
  
  an active filter configured to bi-directionally transfer energy between the output load and the storage capacitor;
  
  wherein a conversion ratio of the active filter is controlled based on the output voltage; and
  
  wherein a conversion ratio of the power source block is at least partially controlled by a parameter related to a voltage on the storage capacitor;
  
  wherein the power source block comprises;
  
  a series switch element;
  
  a shunt switch element;
  
  a switching controller, the switching controller operative to control opening and closing of the series switch element and the shunt switch element, wherein the opening and closing of the series switch element and the shunt switch element generates a switching voltage, and wherein filtering the switching voltage with an output inductor and a load capacitor generates the output voltage;
  
  wherein control of the conversion ratio of the power source block comprises control of the duty cycle of the opening and closing of the series switch element and the shunt switch element, and wherein the duty cycle is controlled by the parameter related to the voltage on the storage capacitor; and
  
  wherein the power source block comprises a current sensor, the current sensor operative to sense an output current of the power source block, wherein control of the conversion ratio is implemented by injecting a voltage proportional to the sensed output current into an error amplifier of the power source block, and wherein the injected voltage divided by the sensed output current is substantially equal to a response time of the power source block divided by a product of the conversion ratio of the active filter and twice a capacitance of the storage capacitor, wherein the response time is time required from a moment a load current of the output load change occurs to a time an inductor current of the output inductor becomes substantially equal to the load current.

10. A method of voltage regulation comprising:
- converting, by a power source block, an input voltage to an output voltage to supply current to an output load,bi-directionally transferring, by an active filter, energy between the output load and a storage capacitor;
  
  controlling a conversion ratio of the active filter based on the output voltage;
  
  at least partially controlling a conversion ratio of the power source block with a parameter related to a voltage on the storage capacitor; and
  
  wherein when a load transient is encountered, the storage capacitor voltage falls to a reduced level, and remains at the reduced level until an end of the load transient.
- View Dependent Claims (11, 12, 13, 14)
- - 11. The method of claim 10, further comprising:
    - controlling opening and closing of a series switch element and a shunt switch element of the power source block, wherein the opening and closing of the series switch element and the shunt switch element generates a switching voltage, and wherein filtering the switching voltage with an output inductor and a load capacitor generates the output voltage; and
      
      at least partially controlling a duty cycle of the opening and closing of the series switch element and the shunt switch element by the voltage on the storage capacitor.
  - 12. The method of claim 11, further comprising:
    - sensing an output current, with a current sensor, of the power source block,controlling the duty cycle with a signal proportional to the sensed output current combined with a signal that is proportional to the voltage on the storage capacitor.
  - 13. The method of claim 12, wherein the switching controller comprises a power source compensation network that includes an error amplifier;
    - and further comprising injecting a signal from the current source directly to an input of the error amplifier.
  - 14. The method of claim 10, further comprising:
    - sensing an output current, with a current sensor, of the power source block, wherein the conversion ratio of the power source block is additionally controlled by a value of the sensed output current.

15. A method of voltage regulation comprising:
- converting, by a power source block, an input voltage to an output voltage to supply current to an output load,bi-directionally transferring, by an active filter, energy between the output load and a storage capacitor;
  
  controlling a conversion ratio of the active filter based on the output voltage;
  
  at least partially controlling a conversion ratio of the power source block with a parameter related to a voltage on the storage capacitor;
  
  controlling opening and closing of a series switch element and a shunt switch element of the power source block, wherein the opening and closing of the series switch element and the shunt switch element generates a switching voltage, and wherein filtering the switching voltage with an output inductor and a load capacitor generates the output voltage;
  
  at least partially controlling a duty cycle of the opening and closing of the series switch element and the shunt switch element by the voltage on the storage capacitor;
  
  wherein the power source block comprises a plurality of phases of switched converters, wherein a phase of each switched converter is offset in time to minimize a variation in a sum of output currents of the plurality of phases of switched converters.
- View Dependent Claims (16)
- - 16. The method of claim 15, further comprising:
    - sensing, by a current sensor, an average output current over all phases of the plurality of phases of switched converters of the power source block, wherein the conversion ratio of the power source block is additionally controlled by a value of the sensed averaged output current.

17. A method of voltage regulation comprising:
- converting, by a power source block, an input voltage to an output voltage to supply current to an output load,bi-directionally transferring, by an active filter, energy between the output load and a storage capacitor;
  
  controlling a conversion ratio of the active filter based on the output voltage;
  
  at least partially controlling a conversion ratio of the power source block with a parameter related to a voltage on the storage capacitor;
  
  wherein the conversion ratio of the power source block is at least partially controlled by the parameter related to the voltage on the storage capacitor during a first mode of the voltage regulator, and the conversion ratio of the power source block is not controlled by the parameter related to the voltage on the storage capacitor during a second mode of the voltage regulator, and the voltage regulator is operative to change between the first mode and the second mode.

18. A method of voltage regulation comprising:
- converting, by a power source block, an input voltage to an output voltage to supply current to an output load,bi-directionally transferring, by an active filter, energy between the output load and a storage capacitor;
  
  controlling a conversion ratio of the active filter based on the output voltage;
  
  at least partially controlling a conversion ratio of the power source block with a parameter related to a voltage on the storage capacitor;
  
  controlling opening and closing of a series switch element and a shunt switch element of the power source block, wherein the opening and closing of the series switch element and the shunt switch element generates a switching voltage, and wherein filtering the switching voltage with an output inductor and a load capacitor generates the output voltage;
  
  at least partially controlling a duty cycle of the opening and closing of the series switch element and the shunt switch element by the voltage on the storage capacitor;
  
  wherein the power source block comprises a current sensor, and further comprising sensing, by a current sensor, an output current of the power source block, wherein control of the conversion ratio is implemented by injecting a voltage proportional to the sensed output current into an error amplifier of the power source block, and wherein the injected voltage divided by the sensed output current is substantially equal to a response time of the power source block divided by a product of the conversion ratio of the active filter and twice a capacitance of the storage capacitor, wherein the response time is time required from a moment a load current of the output load change occurs to a time an inductor current of the output inductor becomes substantially equal to the load current.

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Current Assignee
R2 Semiconductor, Inc.
Original Assignee
R2 Semiconductor, Inc.
Inventors
Audy, Jonathan, Coleman, Edward Paul, Rodal, Eric Bernard, Fisher, David
Primary Examiner(s)
Zhang, Jue
Assistant Examiner(s)
Jackson, Lakaisha

Application Number

US14/941,552
Publication Number

US 20160211750A1
Time in Patent Office

619 Days
Field of Search
US Class Current
CPC Class Codes

H02J 1/10   Parallel operation of dc so...

H02M 1/0009   Devices or circuits for det...

H02M 1/15   using active elements

H02M 3/158   including plural semiconduc...

H02M 3/1584   with a plurality of power p...

Control of conversion ratios of a power source block and a bidirectional active filter

First Claim

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Abstract

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18 Claims

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Control of conversion ratios of a power source block and a bidirectional active filter

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

31 Citations

18 Claims

Specification

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Use Cases

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