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| United States Patent | 6127885 |
| Link to this page | http://www.wikipatents.com/6127885.html |
| Inventor(s) | Colangelo; Thomas Phillip Michael (Hamden, CT) |
| Abstract | Class D amplifiers and methods dynamically modulate the transition zone of
a square wave as a function of the input signal. Stated differently, the
slew rate of the square wave is dynamically modulated as a function of the
input signal. Stated in yet another way, at least one of the rise and fall
times of the square wave is dynamically modulated as a function of the
input signal. By dynamically modulating the transition zone of the square
wave as a function of the input signal, a trapezoidal wave is produced, at
least one of the rise and fall times of which are dynamically modulated as
a function of the input signal. The trapezoidal wave need not have dead
zones. This can reduce and preferably minimize switching losses. The slow
rise and fall transition zone rates can also reduce and preferably
minimize spurious switching noise at zero and low level modulation.
Furthermore, damping network and diode losses may be reduced. Finally,
very small differences of slew rate modulation may be produced, to thereby
accurately quantify small signals. Improved class D amplifier circuits and
methods are thereby provided. |
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Title Information  |
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Drawing from US Patent 6127885 |
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Class D amplifiers including transition zone modulation |
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| Publication Date |
October 3, 2000 |
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| Filing Date |
August 31, 1998 |
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Title Information |
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References |
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U.S. References |
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| | Reference | Relevancy | Comments | Reference | Relevancy | Comments | 5672998
Wittlinger
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Choudhury et al.
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Adrian et al.
Apr,1997 | Your vote accepted
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Dhuyvetter
Jan,1997 | Your vote accepted
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Wagner et al.
Apr,1995 | Your vote accepted
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Posner et al.
Sep,1993 | Your vote accepted
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Morenz
May,1992 | Your vote accepted
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Pennington
Nov,1989 | Your vote accepted
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Killion
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Kaizer et al.
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Killion
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| | Reference | Relevancy | Comments | Dhuyvetter, "A New PWM Generator", Electronic Design, V. 44, No. 20, 1996, p. 30.
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Jun,2007 | Your vote accepted
[0 after 0 votes] | | Nielsen, "High-Fidelity PWM-Based Amplifier Concept for Active Loudspeaker Systems With Very Low Energy Consumption", J. Audio Eng. Soc., V. 45, No. 7/8, Jul./Aug. 1997, pp. 544-570.
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Jun,2007 | Your vote accepted
[0 after 0 votes] | | McGoldrick, "10-A, Full-Bridge Output Hybrid PWM Amplifier Delivers 94% Efficiency", Electronic Design, V. 45, No. 2, p. 109.
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[0 after 0 votes] | | SGS Thomson Microelectronics, "SGS-Thomson Microelectronics TDA7260 High Efficiency Audio PWM Driver", Jun. 1988, pp. 789-801.
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Jun,2007 | Your vote accepted
[0 after 0 votes] | | McLaughlin et al, "Audio Amplifier Efficiency and Balanced Current Design-A New Paradigm", Audio Engineering Society Convention, 1997, Paper 4600 (N-5), pp. 1-6.
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Jun,2007 | Your vote accepted
[0 after 0 votes] | | Nielsen, "Pulse Edge Delay Error Correction (PEDEC)-A Novel Power Stage Error Correction Principle for Power Digital-Analog Conversion", Audio Engineering Society Convention, 1997, Paper 4602 (N-7), pp. 1-30.
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Jun,2007 | Your vote accepted
[0 after 0 votes] | | Williams, "A Monolithic Switching Regulator with 100.mu.V Output Noise", Linear Technology Application Note 70, Oct. 1997, pp. AN70-1 to AN70-72.
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Jun,2007 | Your vote accepted
[0 after 0 votes] | | Sherman, "Class D Amplifiers Provide High-Efficiency for Audio Systems.EDN Design Feature", EDN, V. 40, No. 11, May 25, 1995 pp. 103.
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[0 after 0 votes] | | Swager, "Power ICs: Weighing the Benefits of Integration", EDN, V. 39, No. 14, Jul. 7, 1994, p. 68..
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Market Review |
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Technical Review |
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Claims |
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What is claimed is:
1. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that produces a trapezoidal wave, at least one of the width and the duty cycle of which, and at least one of the rise and fall times of which, are dynamically modulated as a function of the input signal; and
a second circuit that converts the trapezoidal wave into the analog output signal;
wherein the first circuit comprises:
a duty cycle modulator that dynamically modulates the duty cycle of a square wave as a function of the input signal; and
a rate modulator that is responsive to the duty cycle modulator and to the input signal, to dynamically modulate at least one of the rise and fall times of the duty cycle modulated square wave, to produce the trapezoidal wave.
2. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that produces a trapezoidal wave, at least one of the width and the duty cycle of which, and at least one of the rise and fall times of which, are dynamically modulated as a function of the input signal; and
a second circuit that converts the trapezoidal wave into the analog output signal;
wherein the first circuit comprises:
a width modulator that dynamically modulates the width of a square wave as a function of the input signal; and
a rate modulator that is responsive to the width modulator and to the input signal, to dynamically modulate at least one of the rise and fall times of the width modulated square wave, to produce the trapezoidal wave.
3. A class D amplifier according to claim 1 wherein the first circuit increases at least one of the rise and fall times in inverse proportion to the amplitude of the input signal.
4. A class D amplifier according to claim 1 wherein the first circuit increases at least one of the rise and fall times in inverse proportion to the DC value of the input signal.
5. A class D amplifier according to claim 1 wherein the first circuit produces a trapezoidal wave, both the rise and fall times of which are dynamically modulated as a function of the input signal.
6. A class D amplifier according to claim 1 further comprising an AC to DC converter that converts the input signal to DC, and that supplies the input signal so converted to the rate modulator.
7. A class D amplifier according to claim 2 further comprising an AC to DC converter that converts the input signal to DC, and that supplies the input signal so converted to the rate modulator.
8. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that produces a trapezoidal wave, at least one of the rise and fall times of which are dynamically modulated as a function of the input signal; and
a second circuit that converts the trapezoidal wave into the analog output signal,
wherein the second circuit comprises a low pass filter.
9. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that produces a trapezoidal wave, at least one of the rise and fall times of which are dynamically modulated as a function of the input signal;
a second circuit that converts the trapezoidal wave into the analog output signal; and
a linear amplifier that is connected between the first and second circuits, to amplify the trapezoidal wave.
10. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that dynamically modulates at least one of the width and the duty cycle of, and at least one of the rise and fall times of, a square wave as a function of the input signal; and
a second circuit that converts the square wave so modulated into the analog output signal;
wherein the first circuit comprises:
a duty cycle modulator that dynamically modulates the duty cycle of a square wave as a function of the input signal; and
a rate modulator that is responsive to the duty cycle modulator and to the input signal, to dynamically modulate at least one of the rise and fall times of the duty cycle modulated square wave.
11. A class D amplifier that amplifies an input signal to produce an analog output signal comprising:
a first circuit that dynamically modulates at least one of the width and the duty cycle of, and at least one of the rise and fall times of, a square wave as a function of the input signal; and
a second circuit that converts the square wave so modulated into the analog output signal;
wherein the first circuit comprises:
a width modulator that dynamically modulates the width of a square wave as a function of the input signal; and
a rate modulator that is responsive to the width modulator and to the input signal, to dynamically modulate at least one of the rise and fall times of the width modulated square wave.
12. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that dynamically modulates at least one of the rise and fall times of a square wave as a function of the input signal;
a second circuit that converts the square wave so modulated into the analog output signal, wherein the second circuit comprises a low pass filter.
13. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that dynamically modulates at least one of the rise and fall times of a square wave as a function of the input signal;
a second circuit that converts the square wave so modulated into the analog output signal; and
a linear amplifier that is connected between the first and second circuits.
14. A class D amplifier according to claim 12 wherein the first circuit increases at least one of the rise and fall times in inverse proportion to the amplitude of the input signal.
15. A class D amplifier according to claim 12 wherein the first circuit increases at least one of the rise and fall times in inverse proportion to the DC value of the input signal.
16. A class D amplifier according to claim 12 wherein the first circuit dynamically modulates both the rise and fall times of the square wave as a function of the input signal.
17. A class D amplifier according to claim 10 further comprising an AC to DC converter that converts the input signal to DC, and that supplies the input signal so converted to the rate modulator.
18. A class D amplifier according to claim 1 further comprising an AC to DC converter that converts the input signal to DC, and that supplies the input signal so converted to the rate modulator.
19. A class D amplifier that amplifies an input seal to produce an analog output signal, comprising:
a first circuit that dynamically modulates at least one of the width and the duty cycle of, and the slew rate of, a square wave as a function of the input signal; and
a second circuit that converts the square wave so modulated into the analog output signal;
wherein the first circuit comprises:
a duty cycle modulator that dynamically modulates the duty cycle of a square wave as a function of the input signal; and
a rate modulator that is responsive to the duty cycle modulator and to the input signal, to dynamically modulate the slew rate of the duty cycle modulated square wave.
20. A class D amplifier that amplifies an input signal to produce an analog output signal comprising:
a first circuit that dynamically modulates at least one of the width and the duty cycle of, and the slew rate of, a square wave as a function of the input signal; and
a second circuit that converts the square wave so modulated into the analog output signal,
wherein the first circuit comprises:
a width modulator that dynamically modulates the width of a square wave as a function of the input signal; and
a rate modulator that is responsive to the width modulator and to the input signal, to dynamically modulate the slew rate of the width modulated square wave.
21. A class D amplifier according to claim 19 further comprising an AC to DC converter that converts the input signal to DC, and that supplies the input signal so converted to the rate modulator.
22. A class D amplifier according to claim 20 further comprising an AC to DC converter that converts the input signal to DC, and that supplies the input signal so converted to the rate modulator.
23. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that dynamically modulates the sley rate of a square wave as a function of the input signal; and
a second circuit that converts the square wave so modulated into the analog output signal, wherein the second circuit comprises a low pass filter.
24. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that dynamically modulates the slew rate of a square wave as a function of the input signal;
a second circuit that converts the square wave so modulated into the analog output signal; and
a linear amplifier that is connected between the first and second circuit.
25. A class D amplifier according to claim 24 wherein the first circuit increases the slew rate in direct proportion to the amplitude of the input
signal.
26. A class D amplifier according to claim 24 wherein the first circuit increases the slew rate in direct proportion to the DC value of the input signal.
27. A class D amplifier according to claim 24 wherein the first circuit dynamically modulates both the rise and fall slew rates of the square wave as a function of the input signal.
28. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that dynamically modulates at least one of the width and the duty cycle of, and the transition zone of, a square wave as a function of the input signal; and
a second circuit that converts the square wave so modulated into the analog output signal;
wherein the first circuit comprises:
a duty cycle modulator that dynamically modulates the duty cycle of a square wave as a function of the input signal; and
a rate modulator that is responsive to the duty cycle modulator and to the input signal, to dynamically modulate the transition zone of the duty cycle modulated square wave.
29. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that dynamically modulates at least one of the width and the duty cycle of, and the transition zone of, a square wave as a function of the input signal; and
a second circuit that converts the square wave so modulated into the analog output signal;
wherein the first circuit comprises:
a width modulator that dynamically modulates the width of a square wave as a function of the input signal; and
a rate modulator that is responsive to the width modulator and to the input signal, to dynamically modulate the transition zone of the width modulated square wave.
30. A class D amplifier according to claim 28 further comprising an AC to DC converter that converts the input signal to DC, and that supplies the input signal so converted to the rate modulator.
31. A class D amplifier according to claim 29 further comprising an AC to DC converter that converts the input signal to DC, and that supplies the input signal so converted to the rate modulator.
32. A class D amplifier according to claim 29 wherein the first circuit increases the transition zone in inverse proportion to the amplitude of the input signal.
33. A class D amplifier according to claim 29 wherein the first circuit increases the transition zone in inverse proportion to the DC value of the input signal.
34. A class D amplifier according to claim 29 wherein the first circuit dynamically modulates both the rise and fall transition zones as a function of the input signal.
35. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that dynamically modulates the transition zone of a square wave as a function of the input signal; and
a second circuit that converts the square wave so modulated into the analog output signal,
wherein the second circuit comprises a low pass filter.
36. A class D amplifier that amplifies an input signal to produce an analog output signal, comprising:
a first circuit that dynamically modulates the transition zone of a square wave as a function of the input signal;
a second circuit that converts the square wave so modulated into the analog output signal; and
a linear amplifier that is connected between the first and second circuits.
37. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
producing a trapezoidal wave, at least one of the width and the duty cycle of which, and at least one of the rise and fall times of which, are dynamically modulated as a function of the input signal; and
converting the trapezoidal wave into the analog output signal:
wherein the producing step comprises the steps of:
first dynamically modulating the duty cycle of a square wave as a function of the input signal; and
then dynamically modulating at least one of the rise and fall times of the duty cycle modulated square wave as a function of the input signal, to produce the trapezoidal wave.
38. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
producing a trapezoidal wave, at least one of the width and the duty cycle of which, and at least one of the rise and fall times of which, are dynamically modulated as a function of the input signal; and
converting the trapezoidal wave into the analog output signal;
wherein the producing step comprises the steps of:
first dynamically modulating the width of a square wave as a function of the input signal; and
then dynamically modulating at least one of the rise and fall times of the width modulated square wave as a function of the input signal, to produce the trapezoidal wave.
39. A method according to claim 37 wherein the step of then dynamically modulating comprises the steps of:
converting the input signal to DC; and
then dynamically modulating at least one of the rise and fall times of the duty cycle modulated square wave as a function of the input signal so converted.
40. A method according to claim 38 wherein the step of then dynamically modulating comprises the steps of:
converting the input signal to DC; and
then dynamically modulating at least one of the rise and fall times of the width modulated square wave, as a function of the input signal.
41. A method according to claim 37 wherein the producing step comprises the step of increasing at least one of the rise and fall times in inverse proportion to the amplitude of the input signal.
42. A method according to claim 37 wherein the producing step comprises the step of increasing at least one of the rise and fall times in inverse proportion to the DC value of the input signal.
43. A method according to claim 37 wherein the producing step comprises the step of producing a trapezoidal wave, both the rise and fall times of which are dynamically modulated as a function of the input signal.
44. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
producing a trapezoidal wave, at least one of the rise and fall times of which are dynamically modulated as a function of the input signal; and
converting the trapezoidal wave into the analog output signal by low pass filtering the trapezoidal wave into the analog output signal.
45. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
producing a trapezoidal wave, at least one of the rise and fall times of which are dynamically modulated as a function of the input signal;
linearly amplifying the trapezoidal wave; and
converting the trapezoidal wave so amplified into the analog output signal.
46. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating at least one of the width and the duty cycle of, and at least one of the rise and fall times of, a square wave as a function of the input signal; and
converting the square wave so modulated into the analog output signal;
wherein the dynamically modulating step comprises the steps of:
first dynamically modulating the duty cycle of a square wave as a function of the input signal; and
then dynamically modulating at least one of the rise and fall times of the duty cycle-modulated square wave as a function of the input signal.
47. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating at least one of the width and the duty cycle, of and at least one of the rise and fall times of, a square wave as a function of the input signal; and
converting the square wave so modulated into the analog output signal;
wherein the dynamically modulating step comprises the steps of:
first dynamically modulating the width of a square wave as a function of the input signal; and
then dynamically modulating at least one of the rise and fall times of the width modulated square wave.
48. A method according to claim 46 wherein the step of then dynamically modulating comprises the steps of:
converting the input signal to DC; and
then dynamically modulating at least one of the rise and fall times of the duty cycle-modulated square wave as a function of the input signal so converted.
49. A method according to claim 47 wherein the step of then dynamically modulating comprises the steps of:
converting the input signal to DC;
then dynamically modulating at least one of the rise and fall times of the width modulated square wave.
50. A method according to claim 47 wherein the dynamically modulating step comprises the step of increasing at least one of the rise and fall times in inverse proportion to the amplitude of the input signal.
51. A method according to claim 47 wherein the dynamically step comprises the step of increasing at least one of the rise and fall times in inverse proportion to the DC value of the input signal.
52. A method according to claim 47 wherein the dynamically modulating step comprises the step of dynamically modulating both the rise and fall times of the square wave as a function of the input signal.
53. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating at least one of the rise and fall times of a square wave as a function of the input signal; and
converting the square wave so modulated into the analog output signal by low pass filtering the square wave so modulated into the analog output signal.
54. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating at least one of the rise and fall times of a square wave as a function of the input signal;
linearly amplifying the square wave so modulated; and
converting the square wave so modulated and linearly amplified into the analog output signal.
55. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating at least one of the width and the duty cycle of, and the slew rate of, a square wave as a function of the input signal; and
converting the square wave so modulated into the analog output signal;
wherein the dynamically modulating step comprises the steps of:
first dynamically modulating the duty cycle of a square wave as a function of the input signal; and
then dynamically modulating the slew rate of the duty cycle modulated square wave.
56. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating at least one of the width and the duty cycle of, and the slew rate of, a square wave as a function of the input signal; and
converting the square wave so modulated into the analog output signal;
wherein the dynamically modulating step comprises the steps of:
first dynamically modulating the width of a square wave as a function of the input signal; and
then dynamically modulating the slew rate of the width modulated square wave.
57. A method according to claim 55 wherein the step of dynamically modulating comprises the steps of:
converting the input signal to DC; and
then dynamically modulating the slew rate of the duty cycle modulated square wave as a function of the input signal so converted.
58. A method according to claim 56 wherein the step of dynamically modulating comprises the steps of:
converting the input signal to DC; and
then dynamically modulating the slew rate of the width modulated square wave as a function of the input signal so converted.
59. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating the slew rate of a square wave as a function of the input signal; and
converting the square wave so modulated into the analog output signal by low pass filtering the square wave so modulated into the analog output signal.
60. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating the slew rate of a square wave as a function of the input signal;
amplifying the square wave so modulated and
converting the square wave so modulated and amplified into the analog output signal.
61. A method according to claim 59 wherein the dynamically modulating step comprises the step of increasing the slew rate in direct proportion to the amplitude of the input signal.
62. A method according to claim 59 wherein the dynamically modulating step comprises the step of increasing the slew rate in direct proportion to the DC value of the input signal.
63. A method according to claim 59 wherein the dynamically modulating step comprises the step of dynamically modulating both the rise and fall slew rates of the square wave as a function of the input signal.
64. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating at least one of the width and the duty cycle of the transition zone of a square wave as a function of the input signal; and
converting the square wave so modulated into the analog output signal;
wherein the dynamically modulating step comprises the steps of;
first dynamically modulating the duty cycle of a square wave as a function of the input signal; and
then dynamically modulating the transition zone of the duty cycle modulated square wave.
65. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating at least one of the width and the duty cycle of the transition zone of a square wave as a function of the input signal; and
converting the square wave so modulated into the analog output signal;
wherein the dynamically modulating step comprises the steps of:
first dynamically modulating the width of a square wave as a function of the input signal; and
then dynamically modulating the transition zone of the width modulated square wave.
66. A method according to claim 64 wherein the step of dynamically modulating comprises the steps of:
converting the input signal to DC; and
then dynamically modulating the transition zone of the duty cycle modulated square wave as a function of the input signal so converted.
67. A method according to claim 65 wherein the step of dynamically modulating comprises the steps of:
converting the input signal to DC; and
then dynamically modulating the transition zone of the width modulated square wave as a function of the input signal so converted.
68. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating the transition zone of a square wave as a function of the input signal; and
converting the square wave so modulated into the analog output signal by low pass filtering the square wave so modulated into the analog output signal.
69. A method of amplifying an input signal to produce an analog output signal, comprising the steps of:
dynamically modulating the transition zone of a square wave as a function of the input signal;
linearly amplifying the square wave so modulated; and
converting the square wave so modulated and linearly amplified into the analog output signal.
70. A method according to claim 69 wherein the dynamically modulating step comprises the step of increasing the transition zone in inverse proportion to the amplitude of the input signal.
71. A method according to claim 69 wherein the dynamically modulating step comprises the step of increasing the transition zone in inverse proportion to the DC value of the input signal.
72. A method according to claim 69 wherein the dynamically modulating step comprises the step of dynamically modulating both the rise and fall transition zones of the square wave as a function of the input signal.
73. A class D amplifier according to claim 2, wherein the trapezoidal wave is a square wave and wherein the at least one of the rise and fall times is the slew rate or the transition zone of the square wave.
74. A method according to claim 66, wherein the trapezoidal wave is a square wave and wherein the at least one of the rise and fall times is the slew rate or the transition zone of the square wave.
75. A class D amplifier according to claim 10, wherein the trapezoidal wave is a square wave and wherein the at least one of the rise and fall times is the slew rate or the transition zone of the square wave. |
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Claims |
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Description |
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FIELD OF THE INVENTION
This invention relates to amplifier circuits and methods, and more particularly to class D amplifier circuits and methods.
BACKGROUND OF THE INVENTION
Class D amplifiers are well known to those having skill in the art. In particular, power amplifiers may be classified based on their output stages. In a class A amplifier, the output stage conducts for the entire cycle of the input signal. In
contrast, the class B stage is biased at zero DC current. An intermediate stage class between A and B, referred to as class AB, biases the output stage at a non-zero DC current that is generally much smaller than the peak current of the input signal.
Finally, in a class C amplifier, the output stage conducts for an interval shorter than that of the half cycle. Class A, AB and B amplifiers are widely used as output stages of operational amplifiers and audio power amplifiers. Class C amplifiers are
often employed for radio frequency power amplification.
In cont | | |
