DIRECT CONVERSION OUTPUT DRIVER

Abstract

A circuit and method for providing a fully integrated differential boost converter and amplifier. A first half bridge circuit has a first output node and a first switching node. A second half bridge circuit has a second output node and a second switching node. A capacitive load is coupled between the first output node and the second output node. An inductor is coupled between the first switching node and the second switching node. Control modes are provided to couple the first output node to a supply voltage and the first switching node to ground; to couple the first output node to the supply voltage and the second switching node to ground; to couple the second output node to the supply voltage and the first switching node to ground; and to couple the second output node to the supply voltage and the second switching node to ground.

Description

TECHNICAL FIELD

This disclosure relates in general to electronic circuits, and in particular to a circuit and method for direct conversion of an input voltage to a stepped up output voltage.

BACKGROUND

A boost converter or step-up converter is a DC-DC power converter that generates an output voltage that is greater in magnitude than the input voltage. In a typical application, the boost converter is one portion of a circuit solution that generates a high voltage supply, which is then used to drive an amplifier. However, such a solution requires two inductors—one for the boost converter to charge and discharge, and one for the amplifier to block the switching frequency from the capacitive load.

Further, for a capacitive load, such a piezo ceramic speaker, the load can be driven with a continuous time varying signal, such as an audio signal.

Thus, it would be desirable to provide a boost converter for capacitive loads that has a compact design that does not require two inductors, while still providing acceptable fidelity and high efficacy.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a simplified circuit diagram of the switching portion of a differential output driver circuit;

FIG. 2 is a circuit diagram illustrating one embodiment of a differential output driver circuit incorporating the switching portion of FIG. 1;

FIG. 3 is a graph of voltage versus time at the output nodes of the differential output driver circuit of FIG. 2;

FIG. 4 is a graph of voltage versus time at the switching nodes of the differential output driver circuit of FIG. 2;

FIG. 5 is a graph of voltage versus time for control signals applied to the differential output driver circuit of FIG. 2;

FIG. 6A is a graph of voltage versus time at the switching nodes of the differential output driver circuit of FIG. 2 with an increased magnification relative to FIG. 4;

FIG. 6B is a graph of voltage versus time at the switching nodes of the differential output driver circuit of FIG. 2 with an increased magnification relative to FIG. 4; and

FIG. 7 is a simplified block diagram illustrating one embodiment for generating the control signal PWM.

DETAILED DESCRIPTION

This disclosure describes a circuit and method for providing fully integrated differential boost converter and amplifier.

FIG. 1 is a simplified schematic of a full bridge driver circuit 100. The circuit 100 is generally symmetrical, with a differential output section 110 in the middle, a first half-bridge section 120 on the left side for handling positive signals, and a second half-bridge section 130 on the right side for handling negative signals.

The differential output section 110 includes a capacitor 112 coupled between node 125 and node 135 that represents the output load, and an inductor 114 coupled between node 126 and node 136 that provides current to the load under appropriate conditions. Node 125 has the designation OUT_P as it represents the positive side of the differential output voltage V_OUT. Node 135 has the designation OUT_N as it represents the negative side of the differential output voltage V_OUT. Node 126 has the designation SW_P as it represents the positive terminal side of the inductor 114. Node 136 has the designation SW_N as it represents the negative terminal side of the inductor 114.

The first half-bridge section 120 of the circuit 100 includes switches 101_P, 102_P and 103_P, while the second side half-bridge section 130 of the circuit includes corresponding switches 101_N, 102_N and 103_N. Control signals for the switches are not presented in the simplified circuit of FIG. 1, but are described in relation to FIG. 2 below. Switch 103_P is coupled between the supply voltage V_DD and the first output node 125. Switch 102_P is coupled between the first output node 125 and the first switching node 126. Switch 101_P is coupled between the first switching node 126 and ground. Likewise, switch 103_N is coupled between the supply voltage V_DD and the second output node 135. Switch 102_N is coupled between the second output node 135 and the second switching node 136. Switch 101_N is coupled between the second switching node 136 and ground.

As noted above, switches 103_P and 103_N are used to connect the output nodes 125 and 135, respectively, to the supply voltage V_DD. However, to avoid shorting the output when the sign changes, controls will be implemented so that only one of the switches 103_P and 103_N will be closed or enabled at any point in time. For positive signals, switch 103_N holds the output OUT_N at the second output node 135 to V_DD while the positive half-bridge 120 boosts the output OUT_P at the first output node 125 above V_DD. For negative signals, switch 103_P holds the output OUT_P at the first output node 125 to V_DD while the negative half-bridge 130 boosts the output OUT_N at the second output node 135 above V_DD.

Switches 101_P, 101_N, 102_P and 102_N control the charging and discharging of the inductor 114, but are operated and controlled independently of the operation of switches 103_P and 103_N. In one cycle, switches 103_N, 102_N and 101_P are open and switches 103_P, 102_P and 101_N are closed. This shorts the positive side of the inductor 114 to ground, thereby developing a positive voltage across the inductor 114, while the current across the inductor ramps up. However, the resulting differential output OUT_P−OUT_N is negative.

In another cycle, switches 103_P, 102_N and 101_P are open and switches 103_N, 102_P and 101_N are closed. This again shorts the positive side of the inductor 114 to ground, thereby developing a positive voltage across the inductor 114, while the current across the inductor ramps up. In this case, however, the resulting differential output OUT_P−OUT_N is positive.

In yet another cycle, switches 103_N, 102_P and 101_N are open and switches 103_P, 102_N and 101_P are closed. This shorts the negative side of the inductor 114 to ground, thereby developing a negative voltage across the inductor 114, while the current across the inductor ramps down. In this case, the resulting differential output OUT_P−OUT_N is negative.

Finally, in a fourth cycle, switches 103_P, 102_P and 101_N are open and switches 103_N, 102_N and 101_P are closed. This again shorts the negative side of the inductor 114 to ground, thereby developing a negative voltage across the inductor 114, while the current across the inductor ramps down. The resulting differential output OUT_P−OUT_N in this cycle is positive.

FIG. 2 is a schematic of one embodiment of an output driver circuit 200 that incorporates the full bridge driver circuit 100 illustrated in FIG. 1. Control signals SIGN and PWM (and their complements SIGN and PWM) are used to control the operating states of the circuit 200 in order to generate a differential output signal V_OUT which is equal to the difference between the positive output voltage OUT_P at the positive output node 225 and the negative output voltage OUT_N at the negative output node 235. Each of the differential output signals OUT_P, OUT_N is alternately clamped to V_DD or boosted above V_DD as a half-wave rectified signal according to a control scheme.

The output stage of circuit 200 includes a capacitive load 212 coupled between the positive output node 225 (OUT_P) and the negative output node 235 (OUT_N), and an inductor 214 coupled between the positive switching node 226 (SW_P) and the negative switching node 236 (SW_N).

The positive side half-bridge section 220 of the circuit 200 includes switches 201_P, 202_P and 203_P, while the negative side half-bridge section 230 of the circuit includes corresponding switches 201_N, 202_N and 203_N. In an embodiment, all of the switches shown in FIG. 2 are implemented using field effect power transistors.

On the positive half-bridge side 220, switch 203_P has its channel coupled between the supply voltage V_DD and the positive output node 225. The gate of switch 203_P is coupled to the inverted output of buffer 243, which provides the complementary signal SIGN of the control signal SIGN to the gate. Thus, when the control signal SIGN is low (and therefore signal SIGN is high), the switch 203_P is on and the channel conducts the supply voltage V_DD to the positive output node 225. When the control signal SIGN is high (and therefore signal SIGN is low), the switch 203_P is off and the channel does not conduct.

Switch 202_P has its channel coupled between the positive output node 225 and the positive switching node 226. The gate of switch 202_P is coupled to a first output of a non-overlapping driver circuit 222 to receive the inverted control signal PWM. Switch 201_P has its channel coupled between the switching node 226 and ground. The gate of switch 201_P is coupled to a second output of the non-overlapping driver circuit 222 to receive the non-inverted control signal PWM.

The non-overlapping driver circuit 222 has an input terminal coupled to the inverted output of buffer 242, which provides the complement signal PWM of the control signal PWM to the input terminal. The non-overlapping driver circuit 222 thus generates complementary outputs PWM and PWM such that the on-state of switches 202_P and 201_P will be mutually exclusive.

On the negative half-bridge side 230, switch 203_N has its channel coupled between the supply voltage V_DD and the negative output node 235. The gate of switch 203_N is coupled to the control signal SIGN. Thus, when the control signal SIGN is high, the switch 203_N is on and the channel conducts the supply voltage V_DD to the negative output node 235. When the control signal SIGN is low, the switch 203_N is off and the channel does not conduct.

Switch 202_N has its channel coupled between the negative output node 235 and the negative switching node 236. The gate of switch 202_N is coupled to a first output of a non-overlapping driver circuit 232 to receive the control signal PWM. Switch 201_N has its channel coupled between the negative switching node 236 and ground. The gate of switch 201_N is coupled to a second output of the non-overlapping driver circuit 232 to receive the complementary control signal PWM.

The non-overlapping driver circuit 232 has an input terminal coupled to the control signal PWM to generate complementary outputs PWM and PWM to switches 202_N and 201_N, respectively, such that the on-state of switches 202_N and 201_N will be mutually exclusive. This avoids shoot-through current from either of the output nodes to ground. Likewise, although not shown in FIG. 2, a non-overlapping driver circuit is also incorporated for each of switches 203_P and 203_N such that the on-state of these switches is also mutually exclusive. This avoids shorting the output when the SIGN signal changes.

Thus, the inductor has two normal connection states, namely, connected between the positive output node 225 and ground, or between the negative output node 235 and ground. Since one or the other output node is held at the supply voltage V_DD, the magnitude of voltage across the inductor is either V_DD or higher. The sign of voltage across the inductor is defined as positive when switches 202p and 201n are on and negative when switches 202n and 201p are on.

A third inductor state is also provided where the non-overlapping drivers 222, 232 are bypassed to drive the switching nodes 226, 236 to ground simultaneously. This state is used to null the inductor current back to zero, either for a shut down sequence or a sign change. For example, during a shut down event, there is current in the inductor that must drop to zero. Likewise, during a sign change event, i.e., a change in the control signal SIGN, the output nodes are momentarily disconnected from the supply voltage V_DD. The third state allows the inductor to be temporarily and briefly nulled to ground to avoid spikes on the switching nodes while the load is disconnected.

FIG. 3 shows the results of a simulation for normal operation of the driver circuit 200 at the output nodes. Waveform 310 is a single-ended output at positive output node 225 that exhibits half-wave rectification, while waveform 320 is a single-ended output at negative output node 235 that also exhibits half-wave rectification. Thus, when circuit 200 clamps the negative output node 235 to the supply voltage V_DD, the half-bridge driver 220 boosts the voltage output OUT_P at positive output node 225 above the supply voltage V_DD. Likewise, when circuit 200 clamps the positive output node 225 to the supply voltage V_DD, the half-bridge driver 230 boosts the voltage output OUT_N at negative output node 235 above the supply voltage V_DD. The differential signal OUT_N−OUT_P is represented by waveform 330 and is a sine wave that varies in this example between +10V and −10V. Thus, the circuit 200 controls the voltage at nodes 225, 235 such that the minimum voltage for charging and discharging the inductor 214 is V_DD.

FIG. 4 shows the results of a simulation for normal operation of the driver circuit 200 at the switching nodes. Waveform 410 illustrates the voltage at the positive switching node 226 while waveform 420 illustrates the voltage at the negative switching node 236. As is apparent from the figure, each of the switching nodes toggles between ground and the output voltage at the respective output node at a very high frequency, for example 1.2 MHz, and each switching node follows its respective output node. The fact that the voltages at the output nodes are half-wave rectified is also reflected at the respective switching nodes.

FIG. 5 shows an example representation of the control signals PWM and SIGN for normal operation of the driver circuit 200. Waveform 510 represents the SIGN control signal, which is a digital signal that has a value of logical 1 for a positive driven output and a value of logical 0 for a negative driven output. Waveform 520 represents the differential output signal OUT_P−OUT_N, which varies between −10V and +10V and has a sign that follows the control signal SIGN. The alignment of the SIGN signal with the zero crossing of the differential output signal point is flexible and need not be exact. Timing offsets from the edge of the SIGN signal should be subtracted from the minimum inductor voltage V_DD.

Waveform 530 represents the control signal PWM, which varies between 0V and 5V at a high frequency, e.g. 1.2 MHz. Waveform 540 represents the duty cycle for the signal PWM, which controls the differential output voltage. A 50% duty cycle corresponds to zero voltage output, while a duty cycle greater than 50% generates a positive driven signal and a duty cycle less than 50% generates a negative driven signal.

FIG. 6A shows an example representation 601 of how the control signal PWM controls the state of the switching nodes 226, 236 in driver circuit 200. In graph 601, waveform 610 represents the voltage V_SWP at switching node 226, while waveform 620 represents the voltage V_SWN at switching node 236. Graph 601 presents the waveforms 610, 620 at a significantly greater magnification (1 μs per horizontal division) than the waveforms 410, 420 shown in FIG. 4 (200 μs per horizontal division). Thus, the positive switching node 226 toggles between ground and V_DD+V_OUT, while the negative switching node 236 toggles between ground and V_DD.

In FIG. 6B, graph 602 shows waveform 630, which represents the PWM control signal, while waveform 640 represents the inductor current. Graph 602 presents waveform 630 at a greater magnification (1 μs per horizontal division) than the waveform 530 shown in FIG. 5 (200 μs per horizontal division). The control signal PWM toggles between ground and V_DD. The differential voltage across the inductor is V_SWP−V_SWN. When the differential voltage across the inductor is positive, then a positive current will be developed across the inductor. When the differential voltage across the inductor is negative, then a negative current will be developed across the inductor.

FIG. 7 is a simplified block diagram of one circuit embodiment 700 for generating the control signal PWM. A voltage input signal V_IN is combined with a voltage feedback signal V_FB by summing circuit 702, where V_FB is equivalent to the differential voltage V_OUT in FIG. 1. The output of summing circuit 702 is provided to summing circuits 704 and 706. Summing circuit 704 combines the output of summing circuit 702 with a positive voltage reference +V_REF, while summing circuit 706 combines the output of summing circuit 702 with a negative voltage reference −V_REF.

The output of summing circuit 704 is coupled to the inverting input of comparator 708. Likewise, the output of summing circuit 706 is coupled to the inverting input of comparator 710. A current sense signal, namely a voltage representation of the current at the inductor, is provided to the non-inverting inputs of both amplifiers 708 and 710. The output of comparator 708 is coupled to the S (set) input of RS latch 712, while the output of comparator 710 is coupled to the R (reset) input of RS latch 712. The output of the RS latch 712 is the control signal PWM.

Although illustrative embodiments have been shown and described by way of example, a wide range of alternative embodiments is possible within the scope of the foregoing disclosure.

Claims

1. A switching circuit for a differential output driver for a capacitive load, comprising:

a first half bridge circuit having a first output node and a first switching node;

a second half bridge circuit having a second output node and a second switching node, the capacitive load being coupled between the first output node and the second output node;

an inductor coupled between the first switching node and the second switching node;

a control circuit coupled to the first half bridge circuit and to the second half bridge circuit, the control circuit configured to operate the switching circuit with a first control signal and a second control signal, the first control signal having two states including a first state that enables coupling the first output to a supply voltage and a second state that enables coupling the second output to the supply voltage, the second control signal having two states including a first state that enables coupling the first switching node to ground and enables coupling the second switching node the second output, and a second state that enables coupling the second switching node to ground and enables coupling the first switching node to the first output.

2. The switching circuit of claim 1, further comprising:

a first switch coupled between the first output node and the supply voltage, the first switch is open for positive driven signals and the first switch is closed for negative driven signals; and

a second switch coupled between the second output node and the supply voltage, the second switch is closed for positive driven signals and the second switch is open for negative driven signals.

3. The switching circuit of claim 2, further comprising:

the operation of the first switch and the second switch is mutually exclusive.

4. The switching circuit of claim 2, further comprising:

a third switch and a fourth switch coupled in series between the first output node and ground, the first switching node is located at the interconnection of the third and fourth switches; and

a fifth switch and a sixth switch coupled in series between the second output node and ground, the second switching node is located at the interconnection of the fifth and sixth switches;

wherein a first control mode of the switching circuit enables the first state of the first control signal and the first state of the second control signal, such that the first switch is closed, the second switch is open, the third switch is closed, the fourth switch is open, the fifth switch is open, and the sixth switch is closed;

wherein a second control mode of the switching circuit enables the first state of the first control signal and the second state of the second control signal, such that the first switch is closed, the second switch is open, the third switch is open, the fourth switch is closed, the fifth switch is closed, and the sixth switch is open;

wherein a third control mode of the switching circuit enables the second state of the first control signal and the first state of the second control signal, such that the first switch is open, the second switch is closed, the third switch is closed, the fourth switch is open, the fifth switch is open, and the sixth switch is closed; and

wherein a fourth control mode of the switching circuit enables the second state of the first control signal and the second state of the second control signal, such that the first switch is open, the second switch is closed, the third switch is open, the fourth switch is closed, the fifth switch is closed, and the sixth switch is open.

5. The switching circuit of claim 4, further comprising:

a non-overlapping driver coupled to the first switch and to the second switch and configured for mutually exclusive operation of the first switch and the second switch.

6. The switching circuit of claim 3, further comprising:

the operation of the third and fourth switches is mutually exclusive, and the operation of the fifth and sixth switches is mutually exclusive, wherein the third and sixth switches operate together and the fourth and fifth switches operate together.

7. The switching circuit of claim 6, further comprising:

a first non-overlapping driver coupled to the third and fourth switches; and

a second non-overlapping driver coupled to the fifth and sixth switches.

8. The switching circuit of claim 3, further comprising each of the switches is a power field effect transistor.

9. A switching circuit for a differential output driver for a capacitive load, comprising:

a first switch coupled between a first output node and a supply voltage;

a second switch coupled between a second output node and the supply voltage, the capacitive load being coupled between the first output node and the second output node;

a third switch coupled between the first output node and a first switching node;

a fourth switch coupled between the first switching node and ground;

a fifth switch coupled between the second output node and a second switching node;

a sixth switch coupled between the second switching node and ground;

an inductor coupled between the first switching node and the second switching node;

a first control circuit for generating a first control signal, the first control signal having two states including a first state that enables coupling the first output node to the supply voltage and a second state that enables coupling the second output node to the supply voltage; and

a second control circuit for generating a second control signal, the second control signal having two states including a first state that enables coupling the first switching node to ground and enables coupling the second switching node to the second output, and a second state that enables coupling the second switching node to ground and enables coupling the first switching node to the first output.

10. The switching circuit of claim 9, further comprising:

the switching circuit operating in a first control mode that enables the first state of the first control signal and the first state of the second control signal, such that the first switch is closed, the second switch is open, the third switch is closed, the fourth switch is open, the fifth switch is open, and the sixth switch is closed;

the switching circuit operating in a second control mode that enables the first state of the first control signal and the second state of the second control signal, such that the first switch is closed, the second switch is open, the third switch is open, the fourth switch is closed, the fifth switch is closed, and the sixth switch is open;

the switching circuit operating in a third control mode that enables the second state of the first control signal and the first state of the second control signal, such that the first switch is open, the second switch is closed, the third switch is closed, the fourth switch is open, the fifth switch is open, and the sixth switch is closed; and

the switching circuit operating in a fourth control mode that enables the second state of the first control signal and the second state of the second control signal, such that the first switch is open, the second switch is closed, the third switch is open, the fourth switch is closed, the fifth switch is closed, and the sixth switch is open.

11. The switching circuit of claim 9, wherein the operation of the first and second switches is mutually exclusive.

12. The switching circuit of claim 11, further comprising:

a non-overlapping driver coupled to the first switch and to the second switch and configured for mutually exclusive operation of the first switch and the second switch.

13. The switching circuit of claim 11, further comprising:

a first non-overlapping driver coupled to the third and fourth switches; and

a second non-overlapping driver coupled to the fifth and sixth switches.

14. A method for generating a differential output voltage for a capacitive load, comprising:

operating a switching circuit in a plurality of control modes, the switching circuit comprising a first half bridge circuit having a first output node and a first switching node and a second half bridge circuit having a second output node and a second switching node, with the capacitive load coupled between the first output node and the second output node, and an inductor coupled between the first switching node and the second switching node,

wherein a first control mode couples the first output node to a supply voltage and the first switching node to ground, a second control mode couples the first output node to the supply voltage and the second switching node to ground, a third control mode couples the second output node to the supply voltage and the first switching node to ground, and a fourth control mode couples the second output node to the supply voltage and the second switching node to ground.

15. The method of claim 14, further comprising:

providing a first switch coupled between the first output node and the supply voltage, the first switch being open for positive driven signals and the first switch being closed for negative driven signals;

providing a second switch coupled between the second output node and the supply voltage, the second switch being closed for positive driven signals and the first switch being open for negative driven signals;

16. The method of claim 15, wherein the operation of the first switch and the second switch is mutually exclusive.

17. The method of claim 15, further comprising:

providing a third switch and a fourth switch coupled in series between the first output node and ground, the first switching node is located at the interconnection of the third and fourth switches; and

providing a fifth switch and a sixth switch coupled in series between the second output node and ground, the second switching node is located at the interconnection of the fifth and sixth switches; and

generating a first control signal and a second control signal for controlling the switching circuit, the first control signal having two states including a first state that enables coupling the first output node to the supply voltage and a second state that enables coupling the second output to the supply voltage, the second control signal having two states including a first state that enables coupling the first switching node to ground and enables coupling the second switching node to the second output, and a second state that enables coupling the second switching node to ground and enables coupling the first switching node to the first output;

wherein the first control mode of the switching circuit enables the first state of the first control signal and the first state of the second control signal, such that the first switch is closed, the second switch is open, the third switch is closed, the fourth switch is open, the fifth switch is open, and the sixth switch is closed;

wherein the second control mode of the switching circuit enables the first state of the first control signal and the second state of the second control signal, such that the first switch is closed, the second switch is open, the third switch is open, the fourth switch is closed, the fifth switch is closed, and the sixth switch is open;

wherein the third control mode of the switching circuit enables the second state of the first control signal and the first state of the second control signal, such that the first switch is open, the second switch is closed, the third switch is closed, the fourth switch is open, the fifth switch is open, and the sixth switch is closed; and

wherein the fourth control mode of the switching circuit enables the second state of the first control signal and the second state of the second control signal, such that the first switch is open, the second switch is closed, the third switch is open, the fourth switch is closed, the fifth switch is closed, and the sixth switch is open.