VCO circuit with wide output frequency range and PLL circuit with the VCO circuit

US 6,617,933 B2
Filed: 06/21/2001
Issued: 09/09/2003
Est. Priority Date: 09/29/2000
Status: Expired due to Fees

First Claim

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1. A voltage-controlled oscillating circuit receiving supply of a power source voltage to operate comprising:

a voltage generating circuit setting a voltage level of a bias voltage according to a control voltage being different from said power source voltage inputted from the outside, said voltage generating circuit including an operational amplifier, which is an amplifier of a single stage configuration, and receiving supply of said power source voltage to operate, said operational amplifier having first and second input terminals, wherein one of said first and second input terminals is electrically coupled with said control voltage, and an output terminal outputting said bias voltage, and said voltage generating circuit further including a) a feedback portion coupled between said output terminal and another one of said first and second input terminals and b) a non-inverting amplifier circuit using said operational amplifier receiving supply of said power source voltage to operate; and

a ring oscillator circuit generating a clock having a frequency corresponding to said bias voltage, and having an odd-number of inverters, interconnected in a closed ring, and each inverter receiving supply of said bias voltage to operate, wherein each of said inverters includes a p-channel MOS transistor receiving said bias voltage at its source electrode.

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Abstract

A voltage-controlled oscillating circuit according to the present invention includes: a bias voltage generating circuit outputting a bias voltage according to a control voltage; and a ring oscillator circuit receiving supply of the bias voltage to operate. The bias voltage generating circuit generates the bias voltage using a feedback circuit formed by an operational amplifier receiving supply of a power source voltage to operate. Therefore, an influence of a high frequency component overlapped on the power source voltage, that is an influence of noise, is suppressed, thereby enabling stable generation of an output clock having a small variation in phase.

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20 Claims

1. A voltage-controlled oscillating circuit receiving supply of a power source voltage to operate comprising:
- a voltage generating circuit setting a voltage level of a bias voltage according to a control voltage being different from said power source voltage inputted from the outside, said voltage generating circuit including an operational amplifier, which is an amplifier of a single stage configuration, and receiving supply of said power source voltage to operate, said operational amplifier having first and second input terminals, wherein one of said first and second input terminals is electrically coupled with said control voltage, and an output terminal outputting said bias voltage, and said voltage generating circuit further including a) a feedback portion coupled between said output terminal and another one of said first and second input terminals and b) a non-inverting amplifier circuit using said operational amplifier receiving supply of said power source voltage to operate; and
  
  a ring oscillator circuit generating a clock having a frequency corresponding to said bias voltage, and having an odd-number of inverters, interconnected in a closed ring, and each inverter receiving supply of said bias voltage to operate, wherein each of said inverters includes a p-channel MOS transistor receiving said bias voltage at its source electrode.
- View Dependent Claims (3, 4, 5, 6, 7, 8, 9)
- - 3. The voltage-controlled oscillating circuit according to claim 1 or 2, further comprising:
4. The voltage-controlled oscillating circuit according to claim 1 or 2, further comprising:
- a low pass circuit, coupled between a node supplying said power source voltage and said voltage generating circuit, and for removing a high frequency component of said power source voltage.
5. The voltage-controlled oscillating circuit according to claim 4, wherein a cut-off frequency of said low pass circuit is set according to frequency characteristics of said operational amplifier.
6. The voltage controlled oscillating circuit according to claim 1 or 2, wherein said operational amplifier further includes:
- a differential amplifier portion, coupled between a first power source node supplying one of a ground voltage and said power source voltage and a second power source node supplying the other of said ground voltage and said power source voltage, and amplifying and converting a voltage difference between said first and second input terminals into a voltage difference between first and second nodes;
  
  a first cascode amplifier portion forming a first current path between said first power source node and said first node; and
  
  a second cascode amplifier portion forming a second current path between said first power source node and said second node, wherein said output terminal is provided on said second current path, said first cascode amplifier portion alters a first current amount passing through said first current path according to a voltage level of said first node, and said second cascode amplifier portion alters a second current amount passing through said second current path in proportion to said first current amount.
7. The voltage-controlled oscillating circuit according to claim 6, wherein said first current amount is smaller than said second current amount.
8. The voltage-controlled oscillating circuit according to claim 6, whereinsaid differential amplifier portion has:
- a first transistor, electrically coupled between said first power source node and said first node, and having a control terminal coupled with said first input terminal;
  
  a second transistor, electrically coupled between said first power source node and said second node, and having a control terminal coupled with said second input terminal;
  
  a third transistor, electrically coupled between said first node and said second power source node, and receiving a first voltage at a control terminal thereof; and
  
  a fourth transistor, electrically coupled between said second node and said second power source node, and receiving said first voltage at a control terminal thereof;
  
  wherein said first cascode amplifier portion has;
  
  a fifth transistor, electrically coupled between said first power source node and a third node, and having a control terminal coupled with said third node; and
  
  a sixth transistor, electrically coupled between said first node and said third node, and receiving a second voltage at a control terminal thereof;
  
  and wherein said second cascode amplifier portion has;
  
  a seventh transistor, electrically coupled between said first power source node and said output terminal, and having a control terminal coupled with said third node; and
  
  an eighth transistor, electrically coupled between said second node and said output terminal, and receiving said second bias voltage at a control terminal thereof.
9. The voltage-controlled oscillating circuit according to claim 8, whereinsaid first, third, fifth and sixth transistors have a first current drive ability and said second, fourth, seventh and eighth transistors have a second current drive ability, said first current drive ability being smaller than said second current drive ability.

2. A voltage-controlled oscillating circuit receiving supply of a power source voltage to operate comprising:
- a voltage generating circuit setting a voltage level of a bias voltage according to a control voltage being different from said power source voltage inputted from the outside, said voltage generating circuit including an operational amplifier, which is an amplifier of a single stage configuration, and receiving supply of said power source voltage to operate, said operational amplifier having first and second input terminals, wherein one of said first and second input terminals is electrically coupled with said control voltage, and an output terminal outputting said bias voltage, and said voltage generating circuit further including a) a feedback portion coupled between said output terminal and another one of said first and second input terminals and b) an inverting amplifier circuit using said operational amplifier receiving supply of said power source voltage to operate; and
  
  a ring oscillator circuit generating a clock having a frequency corresponding to said bias voltage, and having an odd-number of inverters, interconnected in a closed ring, and each inverter receiving supply of said bias voltage to operate, wherein each of said inverters includes a p-channel MOS transistor receiving said bias voltage at its source electrode.

10. A voltage-controlled oscillating circuit receiving a power source voltage to operate, comprising:
- a voltage generating circuit receiving a control voltage and amplifying the control voltage at a prescribed amplification factor to generate a bias voltage of a voltage level different from that of said control voltage; and
  
  a ring oscillator circuit generating a clock having a frequency according to that of said bias voltage, and having an odd number of inverters interconnected in a closed ring and receives supply of said bias voltage at each of said inverters to operate, wherein said amplification factor is larger than 1, and said voltage generating circuit includes a non-inverting amplifier circuit using an operational amplifier receiving supply of said power source voltage to operate.
- View Dependent Claims (12, 13)
- - 12. The voltage-controlled oscillating circuit according to claim 10 or 11, further comprising:
13. The voltage-controlled oscillating circuit according to claim 10 or 11, further comprising:
- a low pass circuit, coupled between a node supplying said power source voltage and said voltage generating circuit, and for removing a high frequency component of said power source voltage.

11. A voltage-controlled oscillating circuit receiving a power source voltage to operate, comprising:
- a voltage generating circuit receiving a control voltage and amplifying the control voltage at a prescribed amplification factor to generate a bias voltage of a voltage level different from that of said control voltage; and
  
  a ring oscillator circuit generating a clock having a frequency according to that of said bias voltage, and having an odd number of inverters interconnected in a closed ring and receives supply of said bias voltage at each of said inverters to operate, wherein said amplification factor is small than 1, and said voltage generating circuit includes an inverting amplifier circuit using an operational amplifier receiving supply of said power source voltage to operate.

14. A phase-locked loop circuit generating an output clock for operating an internal circuit in synchronism with a reference clock, comprising:
- a phase comparator circuit comparing said reference clock with a feedback clock from said internal clock;
  
  a control circuit setting a voltage level of a control voltage based on a phase comparison result of said phase comparator circuit; and
  
  a voltage-controlled oscillating circuit receiving supply of a power source voltage being different from said control voltage to operate and supply said output clock having a frequency according to said control voltage to said internal circuit, said voltage-controlled oscillating circuit including a voltage generating circuit setting a voltage level of a bias voltage according to said control voltage, said voltage generating circuit having an operational amplifier, which is an amplifier of a single stage configuration, and receiving supply of said power source voltage to operate, said operational amplifier having first and second input terminals, wherein one of said first and second input terminals is electrically coupled with said control voltage, and an output terminal outputting the bias voltage, and said voltage generating circuit further having a feedback portion coupled between said output terminal and another one of said first and second input terminals, and said voltage-controlled oscillating circuit further including a ring oscillator circuit generating a clock, as said output clock, having a frequency corresponding to that of said bias voltage, said ring oscillator circuit having an odd-number of inverters, interconnected in a closed ring, and each inverter receiving supply of said bias voltage to operate.
- View Dependent Claims (15, 16, 17)
- - 15. The phase-locked loop circuit according to claim 14, wherein the one of said first and second input terminals is electrically coupled with said control voltage via a resistor.
  - 16. The phase-locked loop circuit according to claim 14, wherein an other one of said first and second input terminals is electrically coupled with a reference voltage.
  - 17. The phase-locked loop circuit according to claim 14, wherein each of said inverters includes a p-channel MOS transistor receiving said bias voltage at its source electrode.

18. A voltage-controlled oscillating circuit receiving supply of a power source voltage to operate comprising:
- a voltage generating circuit setting a voltage level of a bias voltage according to a control voltage being different from said power source voltage inputted from the outside, said voltage generating circuit including an operational amplifier, which is an amplifier of a single stage configuration, and receiving supply of said power source voltage to operate, said operational amplifier having first and second input terminals, wherein one of said first and second input terminals is electrically coupled with said control voltage, and an output terminal outputting said bias voltage, and said voltage generating circuit further including a feedback portion coupled between said output terminal and another one of said first and second input terminals; and
  
  a ring oscillator circuit generating a clock having a frequency corresponding to said bias voltage, and having an odd-number of inverters, interconnected in a closed ring, and each inverter receiving supply of said bias voltage to operate, wherein the one of said first and second input terminals is electrically coupled with said control voltage via a resistor.

19. A voltage-controlled oscillating circuit receiving supply of a power source voltage to operate comprising:
- a voltage generating circuit setting a voltage level of a bias voltage according to a control voltage being different from said power source voltage inputted from the outside said voltage generating circuit including an operational amplifier, which is an amplifier of a single stage configuration, and receiving supply of said power source voltage to operate, said operational amplifier having first and second input terminals, wherein one of said first and second input terminals is electrically coupled with said control voltage, and an output terminal outputting said bias voltage, and said voltage generating circuit further including a feedback portion coupled between said output terminal and another one of said first and second input terminals; and
  
  a ring oscillator circuit generating a clock having a frequency corresponding to said bias voltage, and having an odd-number of inverters, interconnected in a closed ring, and each inverter receiving supply of said bias voltage to operate, wherein an other one of said first and second input terminals is electrically coupled with a reference voltage.

20. A voltage-controlled oscillating circuit receiving supply of a power source voltage to operate comprising:
- voltage generating circuit setting a voltage level of a bias voltage according to a control voltage being different from said power source voltage inputted from the outside, said voltage generating circuit including an operational amplifier, which is an amplifier of a single stage configuration, and receiving supply of said power source voltage to operate, said operational amplifier having first and second input terminals, wherein one of said first and second input terminals is electrically coupled with said control voltage, and an output terminal outputting said bias voltage, and said voltage generating circuit further including a feedback portion coupled between said output terminal and another one of said first and second input terminals; and
  
  a ring oscillator circuit generating a clock having a frequency corresponding to said bias voltage, and having an odd-number of inverters, interconnected in a closed ring, and each inverter receiving supply of said bias voltage to operate, wherein each of said inverters includes a p-channel MOS transistor receiving said bias voltage at its source electrode.

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Current Assignee
Mitsubishi Denki Kabushiki Kaisha (Mitsubishi Electric Corporation)
Original Assignee
Mitsubishi Denki Kabushiki Kaisha (Mitsubishi Electric Corporation)
Inventors
Ota, Yoshiyuki, Ito, Yoshiaki
Primary Examiner(s)
Pascal, Robert
Assistant Examiner(s)
Glenn, Kimberly E

Application Number

US09/884,931
Publication Number

US 20020039051A1
Time in Patent Office

810 Days
Field of Search

331/25, 331/18, 331/74, 331/34, 331/57
US Class Current

331/25
CPC Class Codes

H03L 7/093 using special filtering or ...

H03L 7/0995 the oscillator comprising a...

VCO circuit with wide output frequency range and PLL circuit with the VCO circuit

First Claim

1 Assignment

0 Petitions

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Abstract

92 Citations

20 Claims

Specification

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VCO circuit with wide output frequency range and PLL circuit with the VCO circuit

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

92 Citations

20 Claims

Specification

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Use Cases

Quick Links

Others