JP5218089B2 - Signal switching circuit - Google Patents

Description

  The present invention relates to an audio device provided with a USB connector, and more particularly to a signal switching circuit for sharing a data terminal of a USB connector as an audio signal terminal.

In recent years, portable devices have become smaller and more multifunctional, and accordingly, a large number of switches and connectors have to be arranged on a small main body. For this reason, miniaturization of connectors has been promoted, but it is still not sufficient, and a method of sharing different signals with one connector has been devised.
A portable digital audio device generally includes a USB connector for downloading music data or the like from a personal computer or the like to the device, and a headphone connector for listening to sound. For this reason, there has been a technique in which a USB connector can also be used as a headphone (earphone) connector (see, for example, Patent Document 1).

FIG. 2 is a diagram showing an example of an internal circuit of G6K-2G-Y (hereinafter simply referred to as a relay) which is a mechanical relay used in such a technique.
The Vbus signal of the USB signal is connected to the 1 pin of the relay 101 and the Vbus terminal of the USB connector 102 via the resistor R, the D + signal of the USB signal is connected to the 5 pin of the relay 101, and the D− signal of the USB signal is connected to the relay 101. Each is connected to 4 pins. The GND signal of the USB signal is connected to the 8 pin of the relay 101 and the GND terminal of the USB connector 102, respectively. The R signal of the audio signal is connected to the 7th pin of the relay 101, the L signal of the audio signal is connected to the 2nd pin of the relay 101, and the GND signal of the audio signal is connected to the GND signal of the USB signal.

  6 pins of the relay 101 are connected to the D + terminal of the USB connector 102, 3 pins of the relay 101 are connected to the D− terminal of the USB connector 102, and a diode D is connected between the 1 pin and the 8 pin of the relay 101. . The relay 101 includes a coil L and two changeover switches S1 and S2, the coil L is connected between the 1st pin and the 8th pin, and the common terminal of the changeover switch S1 is connected to the 3rd pin. The normal contact terminal is connected to pin 2, the normally open terminal is connected to pin 4, the common terminal of changeover switch S2 is connected to pin 6, the normal contact terminal is connected to pin 7, and the normal open terminal is connected to pin 5. ing.

  When the USB connector 102 is connected to a USB connector of a personal computer or the like, a voltage of 5 V is applied between the GND terminal and the Vbus terminal of the USB connector 102, so that the coil L of the relay 101 is connected to the coil L via a resistor R. The current flows, and the connection between the common terminals 3 and 6 of the changeover switches S1 and S2 is switched to the 4 and 5 pins on the side of the normally open terminal. As a result, the D + signal of the USB signal is connected to the D + terminal of the USB connector 102, and the D- signal of the USB signal is connected to the D− terminal of the USB connector 102, so that the digital signal is transmitted between the personal computer and the device. Data communication by can be performed.

  When headphones are connected to the USB connector 102, no voltage is applied to the Vbus terminal of the USB connector 102, so no power is supplied to the coil L, and the connection between the common terminals 3 and 6 of the changeover switches S1 and S2 is as follows. The 2 pins and 7 pins on the normal contact terminal side remain. For this reason, the R signal of the audio signal is input to the D + terminal of the USB connector 102, and the L signal of the audio signal is input to the D− terminal of the USB connector 102, and the audio signal is sent from the device side to the headphones. Can do.

However, since the mechanical relay is used in FIG. 2, there is a problem that the number of parts increases, the shape is large, and the cost is high. In this case, the headphone connector is omitted. The effect of miniaturization was offset.
Thus, it is conceivable to simply replace the mechanical relay with a semiconductor analog switch. However, in such a case, problems described below occur.

FIG. 3 is a diagram showing a circuit example when the mechanical switch of FIG. 2 is replaced with a semiconductor analog switch. In FIG. 3, only the R signal side is shown for the audio signal in order to simplify the description.
The D + signal of the USB signal is connected to the D + terminal of the USB connector 102 via the analog switch AS1. The R signal of the audio signal is connected to the D + terminal of the USB connector 102 via the capacitor C and the analog switch AS2. The inversion control terminal of the analog switch AS1 and the control terminal of the analog switch AS2 are connected to the output terminal of the inverter circuit INV, and the control terminal of the analog switch AS1 and the inversion control terminal of the analog switch AS2 are the input terminal of the inverter circuit INV and the USB connector 102. Are connected to the Vbus terminals. The Vbus terminal of the USB connector 102 is pulled down to the ground voltage GND by a resistor R.

  The audio signal is input to the analog switch AS2 via the coupling capacitor C because it is necessary to cut a DC component in order to output it to the headphones. As a result, the analog switch AS2 is applied with a voltage whose peak-to-peak voltage spans the positive voltage and the negative voltage. If a negative voltage signal is input when the power source of the analog switch AS2 is a single positive voltage source, a large leakage current is generated from the ground voltage GND toward the negative voltage signal. Wake up and cause malfunction. For this reason, the mechanical relay cannot be simply replaced with a semiconductor switch.

  Further, when the on-resistance of the analog switch AS2 is large, not only the power to be sent to the headphones is lost, but also a problem that the damping factor is deteriorated occurs. In order to reduce the on-resistance of the analog switch AS2, it is necessary to increase the area of the switch element on the chip, which causes a problem of increasing the chip area and increasing the cost.

  The present invention has been made to solve such a problem, and can be realized by a semiconductor element without using a mechanical relay, and can suppress an increase in the number of semiconductor chips. The purpose is to obtain.

The signal switching circuit according to the present invention switches between a digital signal and an audio signal whose peak-to-peak voltage spans a positive voltage and a negative voltage in accordance with a switching signal input from the outside, and outputs it to the data terminal of the USB connector. In the signal switching circuit to
An audio amplifier that generates and outputs the audio signal from an external audio signal input from the outside;
A USB amplifier unit having an output circuit having a tri-state configuration for generating and outputting the digital signal from an external digital signal input from the outside;
A negative voltage generation circuit unit that generates and outputs a voltage smaller than the negative peak voltage of the audio signal;
With
The audio amplifier unit is supplied with a negative voltage from the negative voltage generation circuit unit as a low voltage side power source, and the USB amplifier unit is a low voltage side power source according to the switching signal as the negative voltage generation circuit. When the audio signal is selected by the switching signal when either the negative voltage or the ground voltage is supplied from the unit, the audio amplifier unit is activated, and the USB amplifier unit has a high impedance output terminal. When the negative voltage from the negative voltage generation circuit unit is input as the low voltage side power source and the digital signal is selected by the switching signal, the audio amplifier unit sets the output terminal to the high impedance state. And the negative voltage generation circuit unit stops operating to stop outputting the negative voltage, and the USB amplifier unit operates. In which the ground voltage is input as the power supply voltage side.

  Specifically, a switching switch unit that switches a low-voltage power supply to the USB amplifier unit according to the switching signal is provided, and the USB amplifier unit selects the audio signal by the switching signal. When the negative voltage from the negative voltage generation circuit unit is input from the changeover switch unit as the low voltage side power supply, and the digital signal is selected by the switching signal, the low voltage side power supply A ground voltage is input from the changeover switch section.

  Further, the USB amplifier unit may stop its operation and reduce power consumption when the audio signal is selected by the switching signal.

  In addition, the audio amplifier unit may stop its operation and reduce power consumption when the digital signal is selected by the switching signal.

  The audio amplifier unit, the USB amplifier unit, and the negative voltage generation circuit unit may be integrated in a one-chip semiconductor integrated circuit.

  The audio amplifier unit, the USB amplifier unit, the negative voltage generation circuit unit, and the changeover switch unit may be integrated in a one-chip semiconductor integrated circuit.

  According to the signal switching circuit of the present invention, an audio signal for headphones or the like can be output from a USB terminal by using only a semiconductor circuit without using a mechanical relay. This eliminates the need for reducing the size of the device and the circuit, thereby reducing the cost.

Further, since the coupling capacitor that occupies a large mounting area is no longer necessary, a connection pad for connecting the coupling capacitor is also unnecessary, and as a result, a significant reduction in size and cost can be achieved.
Furthermore, since no analog switch is used, the output impedance of the audio signal can be reduced without increasing the chip area.
Furthermore, since it is integrated in a one-chip semiconductor integrated circuit, further downsizing and cost reduction can be achieved.

It is the figure which showed the circuit example of the signal switching circuit in the 1st Embodiment of this invention. It is the figure which showed the circuit example of the conventional signal switching circuit. It is the figure which showed the other circuit example of the conventional signal switching circuit.

Next, the present invention will be described in detail based on the embodiments shown in the drawings.
First embodiment.
FIG. 1 is a diagram showing a circuit example of a signal switching circuit according to the first embodiment of the present invention.
In FIG. 1, the signal switching circuit 1 includes an R audio amplifier 10, an L audio amplifier 20, a USB amplifier 30, a negative voltage generation circuit 40, an inverter circuit 50, a changeover switch SW1, and a USB connector 60. The R audio amplifier 10 and the L audio amplifier 20 form an audio amplifier unit, the USB amplifier 30 forms a USB amplifier unit, the negative voltage generation circuit 40 forms a negative voltage generation circuit unit, and the changeover switch SW1 forms a changeover switch unit.

  The R audio amplifier 10 is an amplifier circuit that amplifies the right signal ARi of the audio stereo signal, amplifies the input audio signal ARi, and generates and outputs an audio signal ARo for driving headphones. The R audio amplifier 10 includes a control input terminal, and a switching signal select is input to the control input terminal. The R audio amplifier 10 operates when the switching signal select is at a high level. When the switching signal select is at a low level, the R audio amplifier 10 stops its operation so that power consumption becomes almost zero and the output terminal is set in a high impedance state.

  Similarly, the L audio amplifier 20 is an amplification circuit that amplifies the left signal ALi of the audio stereo signal, amplifies the input audio signal ALi, and generates and outputs an audio signal ALo for driving headphones. The L audio amplifier 20 also has a control input terminal, and a switching signal select is input to the control input terminal. The L audio amplifier 20 operates when the switching signal select is at a high level. When the switching signal select is at a low level, the operation of the L audio amplifier 20 is stopped, power consumption becomes almost zero, and the output terminal is brought into a high impedance state.

  The USB amplifier 30 is an interface circuit that inputs and outputs digital signals. When a digital signal Digital output from an internal circuit of a device (not shown) is input, the USB amplifier 30 converts the digital signal to Digital + and Digital−, via the corresponding data terminals D + and D− of the USB connector 60. Output to the outside. Further, the USB amplifier 30 outputs the digital signals Digital + and Digital− input from the data terminals D + and D− of the USB connector 60 to a circuit (not shown) inside the device as the digital signal Digital.

  The USB amplifier 30 also has a control input terminal, and an inverted switching signal selectB obtained by inverting the switching signal select by the inverter circuit 50 is input to the control input terminal. Further, the output on the USB connector 60 side of the USB amplifier 30 has a tri-state configuration, and the state of the output terminal of the USB amplifier 30 is controlled by the inversion switching signal selectB. That is, when the inversion switching signal selectB is at the low level, the USB amplifier 30 stops operating because the output terminal is in a high impedance state, and the power consumption becomes almost zero. When the inversion switching signal selectB is at the high level, the USB amplifier 30 operates to generate and output a high or low level signal according to the signal level of the input digital signal Digital.

The negative voltage generation circuit 40 is a DC-DC converter using a charge pump with a capacitor, and is the lowest voltage on the negative side of the peak-to-peak voltage in the audio signals ARo and ALo output from the R audio amplifier 10 and the L audio amplifier 20. A smaller negative voltage Vss is generated and output.
The negative voltage Vss output from the negative voltage generation circuit 40 is supplied to each negative power supply terminal of the R audio amplifier 10 and the L audio amplifier 20, and is further supplied to the terminal A of the changeover switch SW1.
The negative voltage generation circuit 40 also has a control input terminal, and a switching signal select is input to the control input terminal. The negative voltage generation circuit 40 outputs the negative voltage Vss when the switching signal select is at a high level, and stops the operation and stops the supply of the negative voltage Vss when the switching signal select is at a low level.

  The changeover switch SW1 is a changeover switch having a control terminal, and the common terminal C of the changeover switch SW1 is connected to the power supply terminal on the low voltage side of the USB amplifier 30. The terminal B of the changeover switch SW1 is connected to the ground voltage GND, and the changeover signal select is input to the control terminal of the changeover switch SW1. The changeover switch SW1 connects the common terminal C to the terminal A when the changeover signal select is high level, and connects the common terminal C to the terminal B when the changeover signal select becomes low level.

  In such a configuration, when the switching signal select is at a high level, the USB connector 60 is connected to the audio signal. Since the switching signal select is at the high level, the negative voltage generation circuit 40 generates and outputs the negative voltage Vss. The R audio amplifier 10 and the L audio amplifier 20 also operate, amplify the correspondingly input audio signals ARi and ALi, and generate and output audio output signals ARo and ALo. Both the positive and negative power supply voltages Vdd and Vss are input to the R audio amplifier 10 and the L audio amplifier 20, respectively, and each peak-to-peak of the output audio output signals ARo and ALo changes from a positive voltage to a negative voltage. It has become.

  Since the common terminal C of the changeover switch SW1 is connected to the terminal A, the negative voltage Vss is input to the low voltage side power supply terminal of the USB amplifier 30. Furthermore, since the output terminal of the USB amplifier 30 is in a high impedance state and the negative voltage Vss is input to the power supply on the low voltage side, even if a negative voltage appears at the data terminals D + and D− of the USB connector 60. No current flows into the USB amplifier 30.

  Next, when the switching signal select is at a low level, the USB connector 60 is connected to a digital signal. When the switching signal select becomes a low level, the USB amplifier 30 starts operating, and conversely, the R audio amplifier 10 and the L audio amplifier 20 stop operating and put each output terminal into a high impedance state. The negative voltage generation circuit 40 also stops operating and the negative voltage Vss is not output. Further, the common terminal C of the changeover switch SW1 is connected to the terminal B side, and the low-voltage power supply voltage of the USB amplifier 30 is connected to the ground voltage GND.

  That is, the digital signals Digital + and Digital− output from the USB amplifier 30 are output correspondingly from the data terminals D + and D− of the USB connector 60. At this time, since the output terminals of the R audio amplifier 10 and the L audio amplifier 20 are in a high impedance state, the digital signals Digital + and Digital− do not flow into the R audio amplifier 10 and the L audio amplifier 20. Conversely, the output signals of the R audio amplifier 10 and the L audio amplifier 20 do not affect the digital signals Digital + and Digital−.

Further, since the ground voltage GND is connected to the power source on the low voltage side of the USB amplifier 30, it is possible to prevent the digital signals Digital + and Digital− output from the USB amplifier 30 from becoming negative voltages. .
In the first embodiment, the dedicated switching signal select is used as the switching signal. However, as shown in the conventional example of FIG. 3, a signal obtained by inverting the Vbus voltage of the USB connector is used as the switching signal select. May be.

  As described above, the signal switching circuit according to the first embodiment realizes the switching circuit by using only the semiconductor elements. Therefore, all of these circuits can be mounted on a one-chip semiconductor device. Since the coupling capacitor that occupies the mounting area is no longer necessary, a connection pad for connecting the coupling capacitor is also unnecessary, and as a result, significant downsizing and cost reduction can be achieved. In addition, since the analog switch is not inserted in the path for outputting the audio signal, the output impedance can be reduced without increasing the chip area.

DESCRIPTION OF SYMBOLS 1 Signal switching circuit 10 R audio amplifier 20 L audio amplifier 30 USB amplifier 40 Negative voltage generation circuit 50 Inverter circuit 60 USB connector SW1 changeover switch

Special table 2006-519522 gazette

Claims (6)

In a signal switching circuit that switches between a digital signal and an audio signal whose peak-to-peak voltage spans a positive voltage and a negative voltage according to a switching signal input from the outside, and outputs it to the data terminal of the USB connector.
An audio amplifier that generates and outputs the audio signal from an external audio signal input from the outside;
A USB amplifier unit having an output circuit having a tri-state configuration for generating and outputting the digital signal from an external digital signal input from the outside;
A negative voltage generation circuit unit that generates and outputs a voltage smaller than the negative peak voltage of the audio signal;
With
The audio amplifier unit is supplied with a negative voltage from the negative voltage generation circuit unit as a low voltage side power source, and the USB amplifier unit is a low voltage side power source according to the switching signal as the negative voltage generation circuit. When the audio signal is selected by the switching signal when either the negative voltage or the ground voltage is supplied from the unit, the audio amplifier unit is activated, and the USB amplifier unit has a high impedance output terminal. When the negative voltage from the negative voltage generation circuit unit is input as the low voltage side power source and the digital signal is selected by the switching signal, the audio amplifier unit sets the output terminal to the high impedance state. And the negative voltage generation circuit unit stops operating to stop outputting the negative voltage, and the USB amplifier unit operates. Signal switching circuit, wherein a ground voltage is input as the power supply voltage side.   In accordance with the switching signal, the USB amplifier unit includes a changeover switch unit that switches a low-voltage power supply to the USB amplifier unit, and the USB amplifier unit is low when the audio signal is selected by the switching signal. When a negative voltage from the negative voltage generation circuit unit is input from the changeover switch unit as a voltage side power supply and the digital signal is selected by the changeover signal, the low voltage side power supply from the changeover switch unit 2. The signal switching circuit according to claim 1, wherein a ground voltage is input.   3. The signal switching circuit according to claim 1, wherein the USB amplifier unit stops operation and reduces power consumption when the audio signal is selected by the switching signal. 4.   4. The signal switching circuit according to claim 1, wherein the audio amplifier section stops operation and reduces power consumption when the digital signal is selected by the switching signal. 5.   2. The signal switching circuit according to claim 1, wherein the audio amplifier unit, the USB amplifier unit, and the negative voltage generation circuit unit are integrated in a one-chip semiconductor integrated circuit.   3. The signal switching circuit according to claim 2, wherein the audio amplifier unit, the USB amplifier unit, the negative voltage generation circuit unit, and the changeover switch unit are integrated in a one-chip semiconductor integrated circuit.

Images