The technology disclosed herein relates to audio amplifiers and in particular class-D audio amplifiers with improved performance.
Audio amplifiers receive input signals and generate output signals with increased power. For example, when the input signal is a time-varying signal such as an audio signal, the amplifier output signal (i.e., the amplified signal) will have a proportionally greater amplitude than the input signal. The gain of an amplifier describes the ratio between the magnitude of the output and input signals, and the amplifier's bandwidth is the range of frequencies amplified by the amplifier. One goal of an amplifier is to produce an output signal with an acceptable gain, over needed frequencies, without introducing unwanted distortions. Audio amplifiers, for example, are designed to reproduce input audio signals at their output, with desired power levels and with acceptable distortion, over typical audio frequency ranges (e.g., 20 Hz to 20 kHz).
Class-D amplifiers derive a pulse-width modulated (PWM) signal from an input signal and amplify the PWM signal using switching transistors. The amplified signal is then passed through a low-pass filter before generating the output signal. Class-D amplifiers may utilize feedback to reduce distortion and noise in the output signal. One of the challenges with such amplifiers is that even with the benefit of feedback, there are limits to the gain and bandwidth that can be achieved by a class-D amplifier before limitations arise. For example, for certain class-D amplifiers, there exists a limit on how much gain may be achieved before the amplifier suffers from stability issues. Accordingly, there is a need for an improved class-D amplifier design.
As will be discussed in further detail below, the technology disclosed herein relates to amplifiers and in particular to class-D amplifiers with nested feedback loops that improve amplifier performance.
Embodiments of the present technology provide an audio amplifier having, first and second summing nodes, a switch node, and a switching amplifier coupled between the switch node and the first summing node. A filter is coupled to the switch node, and the filter is between the switch mode and a speaker that receives the amplified output signal. A global feedback loop receives a signal portion from filter and provides the signal portion to a third summing node. A nested amplifier portion generates a pulse-width modulated signal driven on the first summing node, and the nested amplifier portion has a first feedback loop nested within second feedback loop. The first feedback loop has a first loop feedback module that provides a first feedback signal from the switch node to the first summing node. The second feedback loop provides a second feedback signal from the switch node to the second summing node. The second feedback loop has a second loop feedback module coupled between the switch node and the second summing node. A second loop integrator module is coupled to the second summing node. A second loop compensator module is coupled to the second loop integrator module and a compensator node, with the second loop integrator module between the second loop compensator module and the compensator node. A second loop forward compensator module is coupled between the second loop compensator module and the first summing node. The global feedback loop can have an outer loop feedback module between the filter and the third summing node, wherein the third summing node receives an amplifier input signal. An outer loop summing module is coupled to the third summing node, and an outer loop forward compensation module is coupled to the outer loop summing module node and the second summing node. The outer loop summing module is between the third summing node and the outer loop forward compensator module.
Another embodiment provides an audio amplifier having first and second summing nodes, a switch node, and a switching amplifier coupled between the switch node and the first summing node. A filter coupled to the switch node is between the switch mode and a speaker that receives the amplified output signal. A nested amplifier portion is configured to generate an amplified signal portion driven on the first summing node. The nested amplifier portion has a first feedback loop nested within second feedback loop. The first feedback loop has a first loop feedback module that provides a first feedback signal portion from the switch node to the first summing node. The second feedback loop provides a second feedback signal portion from the switch node to the second summing node. The second feedback loop has a second loop feedback module coupled between the switch node and the second summing node. A second loop integrator module is coupled to the second summing node. A second loop compensator module is coupled to the second loop integrator module and a compensator node, with the second loop integrator module between the second loop compensator module and the compensator node. A second loop forward compensator module is coupled between the second loop compensator module and the first summing node.
Another embodiment of the present technology provides a class-D amplifier that receives an audio input signal. The amplifier comprises a switching amplifier configured to drive an amplified signal to a switch node based on a pulse-width modulated signal received by the switching amplifier at a first summing node. An inductor/capacitor (LC) filter is coupled to the switch node and configured to generate an amplifier output signal from the amplified signal driven by the switching amplifier. A global feedback loop is coupled to the LC filter output, the input signal, and a global summing node. Nested feedback circuits are configured to generate the pulse-width modulated signal driven on the first summing node based on the input signal. The nested feedback circuits have a first feedback loop nested within second feedback loop. The first feedback loop has a first loop feedback module from the switch node to the first summing node. The second feedback loop has a second loop feedback module coupled to the switch node and a second summing node. A second loop integrator module is coupled to the second summing node and an integrator node. A second loop compensator module is coupled to the integrator node and a compensator node, and a second loop forward compensator module is coupled to the compensator node and the first summing node.
The second loop feedback module can includes a resistor, the second loop integrator module can includes a capacitor and an opamp, the second loop compensator module can includes a resistor, a capacitor, and an opamp. The switching amplifier can include two MOSFETs connected in series, wherein the pulse-width modulated signal is coupled to the gate of both MOSFETs. The amplifier output signal generated by the LC filter can drive a speaker. The amplifier of one or more embodiment can include a third feedback loop coupled to the switch node, the input signal, and the second summing node. The amplifier can have a triangle carrier signal coupled to the first summing node.
Referring now to the drawings,
In the illustrated example, both the input signal 115 and the amplified output signal 110 are analog signals. However, as described herein, in a class-D amplifier 105 the amplifying devices operate as electronic switches operating on received modulated pulses. The illustrated amplifier 105 therefore generates a modulated signal 125 from the input signal 115 using a modulator 120. The modulated signal can be a train of square pulses of fixed amplitude but varying width and separation, and represents the amplitude variations of the analog input signal. The modulated signal can be derived using pulse-width modulation (PWM), pulse density modulation, or other forms of modulation. For example, the modulator can be implemented as a comparator that compares a triangular carrier to the input signal, which generates a series of pulses in which the duty cycle is proportional with the instantaneous value of the input signal.
The modulated signal 125 drives a switching amplifier 130, which generates an amplified modulated signal 135. The frequency content of the amplified modulated signal 135 includes high-frequency content from the modulation process, as well as the content of the input signal 115. The class-D amplifier 105 therefore may include a low-pass filter 140 to filter out the high-frequency content prior to driving an output device, such as the powered speaker 145. The low-pass filter can be implemented, for example, using an inductor and a capacitor (i.e., an LC filter).
Class-D amplifiers may utilize various forms of feedback to provide error control, thereby reducing noise and distortion in the amplified output signal. For example, a class-D amplifier may use feedback from the input to the LC filter to correct for noise on the rail voltages supplying the switching amplifier. Similarly, a class-D amplifier may use feedback from the LC filter output to correct for noise introduced by the filter.
The amplifier 205 includes an inner loop feedback module 240 driven by the output of the switching amplifier 225, at a switch node 235, and drives a summing node 245 at the switching amplifier input. The feedback from the switching amplifier output (i.e., the switch node) to the switching amplifier input (i.e., the summing node) enables the amplifier 205, for example, to correct for errors introduced by the switching amplifier 225. The inner loop feedback module 240 can be implemented, for example, using one or more resistors or other discrete elements.
The amplifier 205 additionally includes an outer feedback module 250, which feeds the amplified output signal 210 of the amplifier 205 to an outer loop summing node 255, which is additionally driven by the buffer stage 220. The outer feedback module 250 can be implemented using, for example, one or more resistors, capacitors, or other discrete elements. The outer loop summing node 255 drives an outer loop summing module 260, which drives an outer loop forward compensation module 265; the outer loop summing module 260 and outer loop forward compensation module 265 collectively compensate for the outer feedback module 250. The outer loop summing module 260 can be implemented as an operational amplifier (“opamp”) with summing error amp input, in which one or more resistors, capacitors, and other discrete elements drive the opamp output back to the negative input of the opamp. The outer loop forward compensation module 265, which drives the summing node 245 and ultimately the switching amplifier 225, can be implemented with one or more resistors, capacitors, or other discrete elements. The outer feedback, or global feedback, from the amplifier output enables the amplifier 205 to correct for errors introduced by the LC filter 230. Furthermore, the outer loop compensators enable further stability and error correction.
In class-D amplifiers, errors introduced between the input to the switching amplifier and the output from the switching amplifier (i.e., across the switching amplifier) commonly dominate the overall performance of the amplifier. That is, the switching amplifier may be the largest contributor to total harmonic distortion plus noise (THD+N) in the amplifier output. As a result, conventional class-D amplifier designs tend to focus on improvements to the error correction of the inner feedback loop (such as the inner loop feedback module 240 illustrated in
The amplifier 205 of the present technology provides additional feedback from the switching amplifier output to obtain further improved performance. For example, a second inner feedback loop can be used to take feedback from the switching amplifier output and close around the inner feedback loop described above (such as the inner feedback described in
The nested feedback 330 includes a first inner feedback loop 340, which includes a first inner loop feedback module 342. The first inner loop feedback module 342 is driven by the output of the switching amplifier 310 at the switch node 335, and drives a first summing node 345 at the switching amplifier input. The first inner loop feedback module 342 can be implemented, for example, using one or more resistors or other discrete elements.
The nested feedback 330 also includes a second inner feedback loop, which includes a second inner loop feedback module 352. The second inner loop feedback module 352, which can be implemented using one or more resistors or other discrete elements, is driven by the output of the switching amplifier 310 at the switch node 335. However, unlike the first inner loop feedback module 342, the second inner loop feedback module 352 drives a different node, such as a second summing node 355. The second summing node 355 is additionally driven by the outer feedback and compensation 325, and is ultimately coupled (via a second loop integrator module 360, a second loop compensator module 365, and a second loop forward compensator module 370, described further below) to the first summing node 345 of the first inner feedback loop. Accordingly, the second inner feedback loop 350 of the nested feedback surrounds the first inner feedback loop 340.
As described above, the second summing node 355 drives the second loop integrator module 360, which then drives the second loop compensator module 365. The second loop integrator module 360 and the second loop compensator module 365 combine to provide compensation for the second inner feedback loop 350. The second loop integrator module 360 can be implemented as an opamp with negative feedback, with a capacitor or other discrete element on the negative opamp feedback path. The second loop compensator module 365 can be implemented as an opamp with negative feedback, with a capacitor and resistor (e.g., in parallel with one another) on the negative opamp feedback path. The second loop compensator module 365 drives the second loop forward compensator module 370, which can be implemented by one or more resistors or other discrete elements. The second loop forward compensator module 365 drives the first summing node 345 of the first inner feedback loop 340, thereby completing the nesting of the second inner feedback loop 350 around the first inner feedback loop 340.
Circuit elements 425 are coupled between signal VSW 410 (a switching amplifier output) and signal VSI 420 (the switching amplifier input), and implement a first inner loop feedback transfer function 430. In the illustrated embodiment, the circuit elements include a resistor 426, a resistor 427, and a resistor 428 connected in series.
Circuit elements 435 are coupled between signal VSW 410 (a switching amplifier output) and VSI2 415, and implement a second inner loop feedback transfer function 440. In the illustrated embodiment, the circuit elements include a resistor 436.
Circuit elements 445 are coupled between VSI2 415 and a signal VII2 441, and implement a second inner loop integrator transfer function 450. In the illustrated embodiment, the circuit elements include an opamp 446, with a capacitor 447 connected to the opamp output and the opamp negative input.
Circuit elements 455 are coupled between VII2 441 and a signal VIL_COMP 442, and implement a second inner loop compensator transfer function 460. In the illustrated embodiment, the circuit elements include a resistor 456, in parallel with a resistor 457 and capacitor 458, that drive the negative input of an opamp 459 from VII2. The circuit elements also include a resistor 461 and capacitor 462, in parallel with one another and connected between the opamp output (VIL_COMP) and the negative input of the opamp.
Circuit elements 465 are coupled between VIL_COMP 442 and signal VSI 420 (i.e., the output of nested feedback circuit 405), and implement a second inner loop forward compensator transfer function 470. In the illustrated embodiment, the circuit elements include a resistor 466.
Though
While
From the foregoing, it will be appreciated that specific embodiments of the invention have been described herein for purposes of illustration, but that various modifications may be made without deviating from the scope of the invention. Accordingly, the invention is not limited except as by the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
6297692 | Nielsen | Oct 2001 | B1 |
10164581 | Andersen | Dec 2018 | B2 |