Reconfigurable Multi-Path Injection Locked Oscillator

US 20150097629A1
Filed: 10/03/2013
Published: 04/09/2015
Est. Priority Date: 10/03/2013
Status: Active Grant

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1. A ring oscillator comprising:

three or more delay cells, each of which comprises a plurality of differential input leads and a differential output lead, wherein each of the plurality of differential input leads comprises one or more inverters,wherein the three or more delay cells are inter-connected forming a plurality of loop paths, wherein each loop path connects the differential output lead of each delay cell to a corresponding differential input lead of another delay cell, wherein each loop path provides an inverter strength determined by a number of inverters in a corresponding differential input lead of each delay cell,wherein the plurality of loop paths are configured to generate an oscillating signal with an operating frequency, and wherein the operating frequency is tunable by digitally adjusting one or more inverter strengths in one or more of the plurality of loop paths.

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Abstract

A ring oscillator comprising three or more delay cells, each of which comprises a plurality of differential input leads and a differential output lead, wherein each of the plurality of differential input leads comprises one or more inverters, wherein the three or more delay cells are inter-connected forming a plurality of loop paths, wherein each loop path connects the differential output lead of each delay cell to a corresponding differential input lead of another delay cell, wherein each loop path provides an inverter strength determined by a number of inverters in a corresponding differential input lead of each delay cell, wherein the plurality of loop paths are configured to generate an oscillating signal with an operating frequency, and wherein the operating frequency is tunable by digitally adjusting one or more inverter strengths in one or more of the plurality of loop paths.

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1. A ring oscillator comprising:
- three or more delay cells, each of which comprises a plurality of differential input leads and a differential output lead, wherein each of the plurality of differential input leads comprises one or more inverters,wherein the three or more delay cells are inter-connected forming a plurality of loop paths, wherein each loop path connects the differential output lead of each delay cell to a corresponding differential input lead of another delay cell, wherein each loop path provides an inverter strength determined by a number of inverters in a corresponding differential input lead of each delay cell,wherein the plurality of loop paths are configured to generate an oscillating signal with an operating frequency, and wherein the operating frequency is tunable by digitally adjusting one or more inverter strengths in one or more of the plurality of loop paths.
- View Dependent Claims (2, 3, 4, 5, 6)
- - 2. The ring oscillator of claim 1, wherein the plurality of differential input leads in each delay cell comprise a primary input lead and at least one auxiliary input lead, wherein the plurality of paths comprise a primary path and at least one auxiliary path, wherein the primary path positively connects the differential output lead of each delay cell to a corresponding primary input lead of another delay cell, and wherein each auxiliary path negatively connects the differential output lead of each delay cell to a corresponding auxiliary input lead of another delay cell.
  - 3. The ring oscillator of claim 2, wherein the primary path is configured to supply a primary driving signal, and each of the at least one auxiliary path is configured to supply an auxiliary driving signal which has a phase earlier than the primary driving signal, and wherein adjusting the inverter strengths in the plurality of loop paths keeps the primary driving signal no less than any of the at least one auxiliary driving signal.
  - 4. The ring oscillator of claim 2, wherein each loop path comprises a number of inverter slices coupled to one or more switches, wherein each inverter strength in a loop path is determined by the number of inverter slices in the loop path, and wherein adjusting the one or more inverter strengths comprises switching in or switching out inverter slices in one or more loop paths.
  - 5. The ring oscillator of claim 4, wherein each inverter slice in the at least one auxiliary path is tri-stated, and wherein adjusting the inverter strengths comprises disabling the at least one auxiliary path such that each inverter slice therein has a high impedance output.
  - 6. The ring oscillator of claim 4, wherein the one or more inverter strengths are digitally adjusted by a single control signal, and wherein the control signal comprises a number of binary bits used to determine whether each inverter slice in the plurality of loop paths should be switched in or switched out.

7. A ring oscillator comprising:
- a plurality of delay cells, each of which comprises a primary input lead, a second input lead, and an output lead, wherein the primary input lead of each delay cell comprises a first number of inverter slices, wherein the second input lead of each delay cell comprises a second number of inverter slices,wherein the plurality of delay cells are coupled to provide a primary path and a second path, wherein the primary path connects the output lead of each delay cell to a corresponding primary input lead of another delay cell, wherein the second path further connects the output lead of each delay cell coupled to a corresponding second input lead of another delay cell, and wherein the primary path and the second path are configured to generate an oscillating signal with an operating frequency; and
  
  a digital controller coupled to the plurality of delay cells and configured to control a first inverter strength in the primary path and a second inverter strength in the second path, wherein the first and second inverter strengths are determined by the first and second numbers of inverter slices, respectively, and wherein controlling at least one of the first and second inverter strengths tunes the operating frequency.
- View Dependent Claims (8, 9, 10, 11, 12, 13, 14, 15)
- - 8. The ring oscillator of claim 7, wherein each of the plurality of delay cells further comprises a third input lead, wherein the third input lead of each delay cell comprises a third number of inverter slices,wherein the plurality of delay cells are further coupled to provide a third path which further connects the output lead of each delay cell coupled to a corresponding third input lead of another delay cell,wherein the third path contributes to the generation of the oscillating signal, andwherein the digital controller is further configured to control a third inverter strength in the third path, wherein the third inverter strength is determined by the third number of inverter slices, and wherein controlling at least one of the first, second, and third inverter strengths tunes the operating frequency.
  - 9. The ring oscillator of claim 8, wherein the plurality of delay cells comprise first, second, third, and fourth delay cells, and wherein, in the primary path, the output lead of the first delay cell is connected to the primary input lead of the second delay cell, the output lead of the second delay cell is connected to the primary input lead of the third delay cell, the output lead of the third delay cell is connected to the primary input lead of the fourth delay cell, and the output lead of the fourth delay cell is connected to the primary input lead of the first delay cell.
  - 10. The ring oscillator of claim 9, wherein, in the second path, the output lead of the first delay cell is further connected to the second input lead of the third delay cell, the output lead of the second delay cell is further connected to the second input lead of the fourth delay cell, the output lead of the third delay cell is further connected to the second input lead of the first delay cell, and the output lead of the fourth delay cell is further connected to the second input lead of the second delay cell.
  - 11. The ring oscillator of claim 10, wherein the primary input lead, the second input lead, and the output lead in each delay cell are all differential leads, each with a positive end and a negative end, and wherein, in the third path, the output lead of the first delay cell is further connected to the third input lead of the fourth delay cell, the output lead of the second delay cell is further connected to the third input lead of the first delay cell, the output lead of the third delay cell is further connected to the third input lead of the second delay cell, and the output lead of the fourth delay cell is further connected to the third input lead of the third delay cell.
  - 12. The ring oscillator of claim 7, wherein controlling the first inverter strength in the primary path comprises determining how many of the first number of inverter slices to use in the primary input lead of each delay cell, wherein controlling the second inverter strength in the second path comprises determining how many of the second number of inverter slices to use in the second input lead of each delay cell, and wherein controlling the first, second, and third inverter strengths keeps the first inverter strength no less than the second inverter strength, and the second inverter strength no less than the third inverter strength.
  - 13. The ring oscillator of claim 12, wherein the first and second numbers of inverter slices in each delay cell are all binary weighted, wherein each inverter slice is coupled to one or more switches, and wherein determining how many of the first and second numbers of inverter slices to use is implemented by switching in or switching out the switches.
  - 14. The ring oscillator of claim 13, wherein controlling the second inverter strength comprises switching each of the second numbers of inverter slices to a tri-state to disable the second path.
  - 15. The ring oscillator of claim 12, wherein controlling the first, second, and third inverter strengths is realized by a single control signal generated by the digital controller, and wherein the single signal comprises four binary bits whose value determine all of the inverter strengths.

16. A method implemented by a ring oscillator that comprises three or more delay cells and a plurality of paths formed by connections among the delay cells, the method comprising:
- generating an oscillating signal that has an operating frequency and an amplitude; and
  
  calibrating the oscillating signal by digitally controlling at least one inverter strength in at least one of the plurality of paths, wherein controlling the at least one inverter strength tunes the operating frequency, or the amplitude, or both.
- View Dependent Claims (17, 18, 19, 20)
- - 17. The method of claim 16, further comprising receiving a reference clock signal as an input to at least one of the delay cells, wherein the operating frequency tracks a frequency of the reference clock signal, and wherein digitally controlling the at least one inverter strength is implemented by digital bits without the need to adjust any load capacitance of the ring oscillator.
  - 18. The method of claim 17, wherein the delay cells comprise first, second, third and fourth delay cells, wherein the plurality of paths comprise first, second, and third paths having first, second, and third inverter strengths, respectively, wherein the digital bits are provided to the ring oscillator as a control code with four binary bits, and wherein a relative relationship between the first inverter strength denoted as psel, the second inverter strength denoted as s1sel, and the third inverter strength denoted as s2sel, is determined by the control code denoted as vco_cal, according to the following mapping table:
  - 19. The method of claim 16, wherein digitally controlling the at least one inverter strength comprises changing a number of inverters connected in a path by switching in or switching out one or more inverters in the path, wherein switching in the one or more inverters causes the operating frequency to increase and the amplitude to decrease, and wherein switching out the one or more inverters causes the operating frequency to decrease and the amplitude to increase.
  - 20. The method of claim 16, wherein calibrating the oscillating signal comprises:
    - setting an initial tuning code; and
      
      iteratively determining a smallest source current that, under an updated tuning code, causes the operating frequency to match a reference frequency and the amplitude to be a smallest amplitude that is equal to or greater than a minimal amplitude specified for the ring oscillator,wherein the updated tuning code in a first iteration is the initial tuning code, wherein the updated tuning code in any other iteration is decremented from a previous iteration, and wherein the updated tuning code and the smallest source current that causes the operating frequency to match the reference frequency and the amplitude to be the smallest amplitude that is equal to or greater than the minimal amplitude are designated as final calibrating settings.

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Current Assignee
Huawei Technologies Co., Ltd. (Huawei Investment & Holding Co., Ltd.)
Original Assignee
Futurewei Technologies Incorporated (Huawei Investment & Holding Co., Ltd.)
Inventors
Chong, Euhan

Granted Patent

US 9,178,498 B2
Time in Patent Office

Days
Field of Search
US Class Current

331/57
CPC Class Codes

H03K 2005/00228 having complementary input ...

H03K 3/0322 with differential cells

Reconfigurable Multi-Path Injection Locked Oscillator

First Claim

2 Assignments

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Reconfigurable Multi-Path Injection Locked Oscillator

First Claim

2 Assignments

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Abstract

15 Citations

20 Claims

Specification

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Solutions

Use Cases

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