JP2010278691A - Audio device recognition apparatus and portable computer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus for recognizing an audio device connected to a jack. <P>SOLUTION: The bias voltage of an ECM is applied to a terminal 9-4, and a transistor 103 detects the voltage potential of the terminal 9-4. When a prescribed magnitude of voltage potential is not detected in the terminal 9-4, a switch 107 is turned on to apply the bias voltage of the ECM to a terminal 9-2, and a transistor 105 detects the voltage potential of a terminal 9-1. When a prescribed magnitude of voltage potential is detected in the terminal 9-1, a control circuit 101 outputs a detection signal which indicates an ECM unit connected to a three-prong plug, to an identifying signal generating circuit 111. When a prescribed magnitude of voltage potential is detected in the terminal 9-4, the control circuit outputs a detection signal which indicates a head set connected to a four-prong plug constituted of the ECM and a headphone, to the identifying signal generating circuit 111. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a technology for recognizing an audio device connected to an audio jack provided on a casing of a portable computer by a plug.

  A portable computer such as a notebook personal computer (hereinafter referred to as a notebook PC) is provided with an audio jack for connecting a microphone and headphones. Usually, two or three dedicated jacks for microphone input and dedicated headphone output are provided in the system casing of the notebook PC. Conventionally, a device called a headset that is used by being attached to the head of a human body with a structure in which a microphone and headphones are integrated can be connected to the notebook PC. The conventional headset is provided with two three-pole plugs for a microphone and a headphone, and these are connected to two dedicated jacks corresponding to the notebook PC, respectively. In recent years, notebook PCs have been further reduced in size, and space saving by reducing the number of audio jacks and cost reduction by reducing the number of parts are required.

  By the way, in a smartphone called iPhone (registered trademark) and a PDA (Personal Digital Assistant) called iPAQ (registered trademark), a headset having one 4-pole plug can be connected to the jack of the main body. Hereinafter, this type of headset is referred to as a combo headset, and the corresponding audio jack is referred to as a combo jack. It would be advantageous in terms of space and cost if it is possible to connect a single combo jack to a notebook PC and connect multiple audio devices such as microphones and headphones conventionally used in notebook PCs in addition to a combo headset. .

  Patent Document 1 discloses an audio device identification method capable of identifying a plurality of types of audio devices connected to a jack interface even when only one jack interface is mounted to maintain miniaturization. To do. In the discrimination method described in this document, the impedance of each pole of the LEFT channel, RIGHT channel, and MIDDLE channel of the plug of the audio device connected to the jack interface is converted into a voltage value, and this is compared with a reference voltage. The type of the audio device connected to the jack interface is automatically determined according to the combination of the three comparison results obtained.

  Patent Document 2 discloses a recognition system that recognizes external devices such as a microphone, a speaker, and a line input device coupled to a computer device. In the recognition system described in this document, a unique impedance signature for a specific external device is generated from the impedance measured with a DC voltage and an AC voltage. Japanese Patent Application Laid-Open No. 2004-228867 determines whether a 4-pole mini plug for audio / video signals or a 3-pole stereo mini plug for headphone signals is connected to the jack, and switches the connection system of the jack signal terminals. A signal switching circuit is disclosed. The microcomputer described in this document indicates that the PDET terminal for detecting the zero potential of the 1F terminal of the jack when the plug is connected, and the potential of the 1D terminal of the jack are different between the 4-pole mini plug and the stereo mini plug. An AHDET terminal for detection is provided.

JP 2007-180742 A JP 2007-122720 A JP 2000-323339 A

  A combo jack provided on the body of iPhone (registered trademark) or iPAQ (registered trademark) can be connected to a combo headset or headphones, but a microphone cannot be connected. When a combo jack is provided on a notebook PC and a dedicated jack for a microphone or headphone that has been conventionally provided is to be removed, the connected device is recognized and the audio circuit of the notebook PC is switched correctly. There is a need. In the method of recognizing a device by measuring impedance as in Patent Document 1 and Patent Document 2, the number of elements of the recognition circuit increases, and the space and cost also increase. Further, the invention of Patent Document 3 recognizes only two types of jacks, and since the microphone is not recognized, it cannot be said to be sufficient for application to a notebook PC.

  In addition, some microphones have a mute button. When the mute button is pressed, the electrical state of the microphone when it is recognized as a microphone changes. Therefore, it is necessary to take measures to prevent the recognition result from changing when the mute button is pressed. . In addition, it is assumed that plugs of audio devices that are not subject to recognition will be inserted into the combo jack, but even in this case, it is necessary to take care not to damage the audio device. There is.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an identification apparatus that can identify a plurality of audio devices connected to one audio jack by a simple method. Furthermore, an object of the present invention is to provide an identification apparatus capable of identifying three types of audio devices. A further object of the present invention is to provide an identification apparatus capable of connecting four or more types of audio devices. Furthermore, an object of the present invention is to provide an identification device that does not damage an audio device that is not subject to identification even if it is connected. A further object of the present invention is to provide an identification method executed in such an identification apparatus, a semiconductor device equipped with such an identification apparatus, and a portable computer.

  In the audio jack, a first terminal, a second terminal, a third terminal, and a fourth terminal are arranged in order. The direction of placement can be from the back of the audio jack or from the entrance side, consistent with the placement of the plug electrodes. One of a plurality of audio devices each connected to a plug is connected to the audio jack. The recognizing device sends an identification signal to the CODEC, and operates according to the audio device connected to the audio jack. A bias voltage of the electret condenser microphone is applied to the fourth terminal during the recognition operation of the audio device and at least while the audio jack is being used. First, when the potential of the fourth terminal is detected by the first potential detection circuit and a potential of a predetermined magnitude is not detected at the fourth terminal, the bias voltage of the electret condenser microphone is applied to the second terminal. Applied.

  A detection signal indicating that the control circuit is the first audio device connected to the three-pole plug when the second potential detection circuit detects a potential of a predetermined magnitude at the first terminal. Is output. As an example, the first audio device is an electret condenser microphone unit in which electrodes of a three-pole plug that respectively contact the first terminal and the second terminal are connected to each other inside. When the first potential detection circuit detects a potential having a predetermined magnitude, the control circuit outputs a detection signal indicating that the second audio device is connected to the four-pole plug. The second audio device is, for example, a headset composed of an electret condenser microphone used by supplying a bias voltage to the fourth terminal and stereo headphones. The control circuit maintains the detection signal indicating the second audio device until the four-pole plug is pulled out of the audio jack, so that even if the mute button is pressed, the control circuit recognizes the detection signal once and correctly. There is no output.

  When the second potential detection circuit does not detect a potential having a predetermined magnitude, the control circuit outputs a detection signal indicating the third audio device connected to the audio jack to the three-pole plug. The third audio device is in one example a stereo headphone or a stereo speaker with an amplifier. Since a stereo headphone and a stereo speaker with an amplifier do not require a bias voltage, the control circuit turns off the switch in response to the second potential detection circuit not detecting a predetermined potential.

  According to the present invention, it is possible to provide an identification apparatus capable of identifying a plurality of audio devices connected to one audio jack by a simple method. Furthermore, according to the present invention, an identification device capable of identifying three types of audio devices can be provided. Furthermore, according to the present invention, an identification device capable of connecting four or more types of audio devices can be provided. Furthermore, according to the present invention, it is possible to provide an identification device that does not damage an audio device that is not subject to identification even if it is connected. Furthermore, according to the present invention, it is possible to provide an identification method executed in such an identification device, a semiconductor device and a portable computer equipped with such an identification device.

FIG. 2 is an external view of a notebook PC and a combo headset that can be connected to the notebook PC. It is a functional block diagram which shows the main structures of notebook PC. It is a figure which shows the structure of a combo headset, and the equivalent circuit of ECM. It is a figure which shows the structure of an ECM unit, a stereo earphone unit, and a monaural earphone unit. It is a functional block diagram of the identification circuit which identifies the audio device connected to the jack. It is a flowchart which shows the procedure in which an identification circuit identifies an audio device.

  FIG. 1A is an outline view of a notebook PC 10 according to an embodiment of the present invention, and FIG. 1B is an outline view of a combo headset 50 that can be connected to the notebook PC 10. The notebook PC 10 includes a system housing 3 having a keyboard mounted on the surface thereof and housing an electronic device therein, and an LCD housing 1. A plurality of electronic devices are mounted inside the system housing 3. The system housing 3 is provided with one combo jack 9.

  The combo headset 50 can also be connected to an iPhone (registered trademark), and an electret condenser microphone (ECM) 55, a left headphone 51, a right headphone 53, and a mute button 57 are connected to one 4-pole plug 59. Has been. The mute button on a combo headset is sometimes called an Answer / end button or a multi-function button. Note that the headphones having the structure illustrated in FIG. 1B are also referred to as earphones, and in this specification, headphones and earphones are not distinguished. The combo headset 50 connects the 4-pole plug 59 to the combo jack 9 to send the audio signal collected by the ECM 55 to the notebook PC 10, and the audio data generated by the notebook PC 10 from the left headphones 51 and the right headphones 53. Can be output. The combo jack 9 is connected to an ECM connected to a 3-pole plug, a stereo headphone connected to a 3-pole plug, a stereo speaker with an amplifier connected to a 3-pole plug, and a 2-pole plug. It is also possible to connect and use four or more audio devices such as monaural earphones, and the identification method will be described with reference to the flowchart of FIG.

  FIG. 2 is a functional block diagram showing the main configuration of the notebook PC 10. Connected to the north bridge 13 are a CPU 11, a main memory 15, a video controller 17, and a south bridge 19. An LCD 19 is connected to the video controller 17. An audio controller 21 is connected to the south bridge 19 via an HDA (High Definition Audio) bus interface, and an HDD 23 is connected via an SATA (Serial Advanced Technology Attachment) interface. Further, an LPC bus 25 is connected to the south bridge 19. An embedded controller (EC) 27, a flash ROM 29, and the like are connected to the LPC bus 25.

  FIG. 3A is a diagram showing the configuration of the combo headset 55. As shown in FIG. Four electrodes are formed on the four-pole plug 59 in the order of reference numerals 59-1, 59-2, 59-3, and 59-4 from the tip. The electrode 59-1 is connected to the signal terminal of the left headphone 51, the electrode 59-2 is connected to the signal terminal of the right headphone 53, and the electrode 59-4 is connected to the drain terminal D of the ECM55. The electrode 59-3 is connected to the ground terminal of the left headphone 51, the ground terminal of the right headphone 53, and the source terminal S of the ECM 55. A mute button 57 is connected between the electrode 59-3 and the electrode 59-4.

  FIG. 3B is a diagram illustrating an equivalent circuit of the ECM 55. The electret capacitor 65 has a conductive diaphragm and a fixed electrode facing each other, and a dielectric (electret) is provided on any of these. One of the diaphragm and the fixed electrode is connected to the gate electrode of the junction type field effect transistor (FET) 61, and the other is connected to the source terminal S. The drain electrode of the FET 61 is connected to the bias power source Vcc1 (see FIG. 5) via the drain terminal D, and the source electrode is connected to the ground E (see FIG. 5) via the source terminal S. A high resistance element 63 is connected between the gate electrode and the source electrode of the FET 61. When the electret condenser 65 receives sound, the diaphragm vibrates and the capacitance changes. An audio signal corresponding to the change in capacitance is input to the gate electrode of the FET 61, and an AC voltage corresponding to the audio signal is output from the drain electrode of the FET 61. Between the drain electrode and the source electrode of the FET 61, an internal resistance 67 of about 0.5 KΩ to 1 KΩ is formed equivalently due to the structure of the FET 61, and a drain-source current flows.

  FIG. 4A is a diagram illustrating a configuration of the ECM unit 70. Three electrodes are formed on the three-pole plug 73 in the order of reference numerals 73-1, 73-2, and 73-3 from the tip. The electrodes 73-1 and 73-2 are short-circuited, and both are connected to one end of the mute button 75, and the other end of the mute button 75 is connected to the signal terminal of the ECM 71. The electrode 73-3 is connected to the ground terminal of the ECM 71. FIG. 4B is a diagram showing a configuration of the stereo earphone unit 80. Three electrodes are formed in the three-pole plug 85 in the order of reference numbers 85-1, 85-2, and 85-3 from the tip. The electrode 85-1 is connected to the signal terminal of the left earphone 81, and the electrode 85-2 is connected to the signal terminal of the right earphone 83. The ground terminals of the left earphone 81 and the right earphone 83 are connected to the electrode 85-3.

  The configuration of the stereo speaker with amplifier is the same as that of the stereo earphone unit 80. FIG. 4C is a diagram illustrating a configuration of the monaural earphone unit 90. Two electrodes are formed on the two-pole plug 93 in the order of reference numbers 93-1 and 93-3 from the tip. The electrode 93-1 is connected to the signal terminal of the earphone 91, and the electrode 93-2 is connected to the ground terminal of the earphone 91. It should be noted that the ECM unit 70 and the stereo earphone unit 80 can be integrated into a two-plug headset.

  FIG. 5 is a block diagram showing the function of the identification circuit 100 that identifies the audio device connected to the combo jack 9. The identification circuit 100 includes devices mounted on the combo jack 9 and the audio controller 21. The combo jack 9 is located at a position corresponding to the electrode 59-1, the electrode 59-2, the electrode 59-3, and the electrode 59-4 when the four-pole plug 59 of the combo headset 50 is inserted. To 4 are formed in the order of reference numerals 9-1, 9-2, 9-3, and 9-4. The combo jack 9 is further formed with a detection piece 9-6 and a trigger terminal 9-5 made of an insulator.

  The audio controller 21 includes transistors 103 and 105, a single-pole single-throw switch 107, a double-pole / double-throw switch 109, a control circuit 101, an identification signal generation circuit 111, and a CODEC 113. Among these, the identification circuit 100 is composed of devices excluding the CODEC 113. The switches 107 and 109 can be composed of MOS type FETs. When either the 4-pole plug 59 or the 3-pole plugs 73 and 85 are inserted into the combo jack 9, the identification circuit 100 is connected to the notebook PC 10 with the combo headset 50, the ECM unit 70, or the stereo earphone unit. The operation of the CODEC 113 is set by identifying which of the 80 audio devices is connected. The identification circuit 100 connects the stereo earphone unit 80 to the combo jack 9 when the two-prong plug 93 of the monaural earphone unit 90 or a stereo speaker with an amplifier is inserted as described later. However, the monaural earphone unit 90 or the stereo speaker operates normally.

  The transistor 103 generates a detection signal when the four-pole plug 59 of the combo headset 50 is inserted into the combo jack 9. The transistor 105 generates a detection signal when the three-pole plug 73 of the ECM unit 70 is inserted into the combo jack 9. The change-over switch 107 applies a voltage for detecting whether the three-pole plug 73 or the three-pole plug 85 is inserted into the combo jack 9 to the signal terminal 9-2 according to the control signal sent from the control circuit 101. Or to apply a bias voltage to the ECM unit 70. The changeover switch 109 switches the signal line connecting the CODEC 113 and the combo jack 9 according to the type of the audio device connected to the combo jack 9 according to the control signal sent from the control circuit 101. The control circuit 101 controls the operation of the switches 107 and 109, and generates three types of detection signals corresponding to the types of connected audio devices based on the detection signals generated by the transistors 103 and 109. Send to circuit 111.

  The identification signal generation circuit 111 generates an identification signal composed of a plurality of voltage values corresponding to the plurality of detection signals received from the control circuit 101, and sends the identification signal to the SENSE terminal of the CODEC 113. The CODEC 113 is an A / D converter that mainly converts an analog signal received from a microphone into a digital signal, and a D / A converter that converts a digital signal received from a program executed by the CPU 11 into an analog signal for output to a headphone. It is configured. The CODEC 113 includes two terminals MIC1 and MIC2 for microphones, and two terminals HP_R and HP_L for headphones, which are shown as an example. The / D converter or the D / A converter is operated to perform an operation corresponding to the type of audio device connected to the combo jack 9.

  When the CODEC 113 receives the identification signal indicating the combo headset 50, the audio signal input from the MIC1 terminal is converted into a digital signal by the A / D converter, sent to the south bridge 19, and received from the south bridge. The digital signal is converted by the D / A converter and output from the HP_R terminal and the HP_L terminal. When the CODEC 113 receives the identification signal indicating the ECM unit 70, the CODEC 113 functions only the A / D converter, converts the analog signal input from the MIC2 terminal into a digital signal, and sends it to the south bridge. When the CODEC 113 receives the identification signal indicating the stereo microphone unit 80, the CODEC 113 functions only the D / A converter, converts the digital signal received from the south bridge into an analog signal, and outputs the analog signal from the HP_R terminal and the HP_L terminal. .

  When the 4-pole plug 59 is inserted into the combo jack 9, the signal terminals 9-1, 9-2, 9-3, 9-4 are respectively connected to the electrodes 59-1, 59-2, 59-3, 59-. 4 is contacted. When the three-pole plug 73 is inserted into the combo jack 9, the signal terminals 9-1 and 9-2 are in contact with the electrodes 73-1 and 73-2, respectively, and the signal terminals 9-3 and 9-4 are respectively electrodes. 7-3. When the three-pole plug 85 is inserted into the combo jack 9, the signal terminals 9-1 and 9-2 are in contact with the electrodes 85-1 and 85-2, respectively, and the signal terminals 9-3 and 9-4 are respectively electrodes. Contact 85-3. When the two-pole plug 93 is inserted into the combo jack 9, the signal terminal 9-1 contacts the electrode 93-1, and the signal terminals 9-2, 9-3, and 9-4 are respectively connected to the electrode 93-2. To touch.

  The signal terminal 9-1 is connected to the switch 109 and the base of the transistor 105. The signal terminal 9-2 is connected to one terminal of the switch 107 and the switch 109. The other terminal of the switch 107 is connected to the bias power supply Vcc2 of the ECM 71 via a resistor. The voltage of the bias power supply Vcc2 is 3V in this embodiment. The signal terminal 9-3 is connected to the ground E. The signal terminal 9-4 is connected to the bias power source Vcc1 of the ECM 55 via a resistor. The voltage of the bias power supply Vcc1 is 3V in this embodiment. Further, the signal terminal 9-4 is connected to the base of the transistor 103 and the MIC1 terminal of the CODEC 113. The trigger terminal 9-5 is connected to the pull-up power supply Vcc5 via a resistor. When no plug is inserted into the combo jack 9, the trigger terminal 9-5 is at the potential of the pull-up power supply Vcc5.

  The detection piece 9-6 and the trigger terminal 9-5 constitute a trigger circuit that detects that any plug is inserted into the combo jack 9. When any plug is inserted into the combo jack 9, the detection piece 9-6 that contacts the electrode at the tip of each plug moves, and the trigger terminal 9-5 is connected to the ground E to trigger terminal 9- The trigger circuit asserts when the potential of 6 becomes zero. The trigger circuit negates the potential when the plugs are pulled out from the combo jack 9. The switch 109 is connected to the MIC2 terminal, HP_R terminal, and HP_L terminal of the CODEC 113. When the switch 109 is switched to one side, the signal terminal 9-2 is connected to the HP_R terminal, and the signal terminal 9-1 is connected to the HP_L terminal. Switch 109 also connects signal terminal 9-1 to the MIC2 terminal when switched to the other. The collector of the transistor 103 is connected to the power supply Vcc3 via a resistor, and the emitter is connected to the ground E. The collector of the transistor 105 is connected to the power supply Vcc4 through a resistor, and the emitter is connected to the ground E. The collectors of the transistor 103 and the transistor 105 are connected to the control circuit 101, respectively. The identification signal generation circuit 111 is connected to the SENSE terminal of the CODEC 113 and the control circuit 101.

  FIG. 6 is a flowchart showing a procedure for the identification circuit 100 to identify an audio device. When the power of the notebook PC 10 is turned on, a bias voltage to be supplied to the ECM 55 of the combo headset 50 is applied to the signal terminal 9-4 in block 201. In block 203, the control circuit 101 that has detected that the trigger circuit has been asserted when any of the plugs 59, 73, 85 is inserted into the combo jack 9 operates the switch 109 in block 205 to operate the signal terminal 9. -2 and 9-1 are connected to the HP_R terminal and HP_L terminal of the CODEC 113, respectively.

  Subsequently, in block 207, if the control circuit 101 determines that the potential of the signal terminal 9-4 is equal to or higher than a predetermined value due to the operation of the transistor 103, the process proceeds to block 209 and the audio connected to the combo jack 9. The device recognizes that it is a combo headset 50 and sends a detection signal indicating the combo headset 50 to the identification signal generation circuit 111. As shown in FIG. 3B, the FET 67 of the ECM 55 is equivalently formed with an internal resistor 67 in a normal state where no audio signal is input to the gate. The value of the internal resistance 67 varies depending on the manufacturer and type of the FET. At this time, the predetermined potential for recognizing the combo headset 50 is about 0.5V to 1V. The identification signal generation circuit 111 that has received the detection signal sends a voltage corresponding to the identification signal of the combo headset 50 to the CODEC 113, and the CODEC 113 that has received the voltage operates in accordance with the combo headset 50.

  On the other hand, as shown in FIG. 4, when either the three-pole plug 73 or the three-pole plug 85 is inserted into the combo jack 9, the signal terminal 9-4 and the signal terminal 9-3 are respectively connected to the electrode 73-. 3 and 85-3, since the potential of the signal terminal 9-4 becomes zero, the combo headset 50 is not detected by the procedure of the block 207, and either the ECM unit 70 or the stereo earphone unit 80 is detected. Detect a connection. As shown in FIG. 3A, the combo headset 50 includes a mute button 57. When the mute button 57 is pressed by the user, the electrodes 59-3 and 59-4 of the 4-pole plug 59 are short-circuited, and the potential of the signal terminal 9-4 transitions to zero. Therefore, even if the control circuit 101 detects the connection of the combo headset 50 once based on the potential of the signal terminal 9-4, the control circuit 101 erroneously recognizes that a different audio device has been detected by pressing the mute button 57 and identifies it. A new erroneous detection signal is output to the signal generation circuit 111.

  In block 211, the control circuit 101 performs an operation for maintaining the result detected in block 209 even when the potential of the signal terminal 9-4 transitions to zero. This can be realized by a known latch circuit that latches a detection signal indicating the combo headset 50. Therefore, even when the mute button 57 is pressed, the operation of the CODEC 113 and the operation of the switch 109 do not change. In block 213, the potential of the trigger terminal 9-5 is restored by pulling out the 4-pole plug 59 from the combo jack 9, and the trigger circuit is negated. In block 215, the control circuit 101 is based on the negation of the trigger circuit. Then, by releasing the state of the latch circuit performed in block 211, preparation for detection of the plug to be inserted next is made and the process returns to block 203.

  When the potential of the signal terminal 9-4 is less than the predetermined value in block 207, the control circuit 101 turns on the switch 107 in block 217 and applies a bias voltage to the ECM 71 of the ECM unit 70 to the signal terminal 9-2. This bias voltage is also used to distinguish between the ECM unit 70 and the stereo earphone unit 80. In block 219, if the control circuit 101 determines that the potential of the signal terminal 9-1 is equal to or higher than a predetermined value by the operation of the transistor 105, the control circuit 101 proceeds to block 221 and the audio device connected to the combo jack 9 is the ECM unit. 70 and sends a detection signal indicating the ECM unit 70 to the identification signal generation circuit 111. The identification signal generation circuit 111 that has received the detection signal sends a voltage corresponding to the identification signal of the ECM unit 70 to the CODEC 113, and the CODEC 113 that has received the voltage operates in accordance with the ECM unit 70. Since the mute button 75 of the ECM unit 70 is connected in series to the signal line, it does not affect the identification result even when pressed, but like the mute button 57 of the combo headset 50, the electrode 73 -2 and the electrode 73-3 are connected so as to be short-circuited, the control circuit 101 is desirably provided with a latch circuit.

  As shown in FIG. 4A, in the ECM unit 70, the electrode 73-2 in contact with the signal terminal 9-2 of the three-pole plug 73 and the electrode 73-1 in contact with the signal terminal 9-1 are internally provided. Short circuit. Therefore, when the three-pole plug 73 is inserted, both the signal terminal 9-1 and the signal terminal 9-2 are at a potential provided by the bias power supply Vcc2. On the other hand, as shown in FIG. 4B, in the stereo earphone unit 80, the electrode 85-2 that contacts the signal terminal 9-2 of the three-pole plug 85 and the signal terminal 9-1 are contacted. Since the electrode 85-1 is internally separated, the potential of the signal terminal 9-1 is not affected by the potential of the signal terminal 9-2, and the ECM unit 70 can be distinguished from the stereo earphone unit 80. it can. In block 223, the control circuit 101 switches the switch 109 so that the signal terminal 9-1 is connected to the MIC2 terminal. The procedure of block 225 is the same as that of block 213.

  In block 219, when the control circuit 101 determines that the potential of the signal terminal 9-1 is less than a predetermined value due to the operation of the transistor 105, the control circuit 101 proceeds to block 227, and the audio device connected to the combo jack 9 is reached. Recognizes the stereo earphone unit 80 and sends a detection signal indicating the stereo earphone unit 80 to the identification signal generation circuit 111. The identification signal generation circuit 111 that has received the detection signal sends a voltage corresponding to the identification signal indicating the stereo earphone unit 80 to the CODEC 113, and the CODEC 113 that has received the voltage operates in accordance with the stereo earphone unit 80. . Since the stereo earphone unit 80 does not require a bias power supply, the control circuit 101 turns off the switch 107 in block 229. The procedure of block 231 is the same as that of block 213. A stereo speaker connected to a three-pole plug and incorporating an amplifier is identified as a stereo earphone unit 80 in block 227 and outputs sound when the three-pole plug is inserted into the combo jack 9. be able to.

  Here, the operation of the identification circuit 100 when the two-pole plug 93 of the monaural earphone unit 90 is connected to the combo jack 9 will be described. In the bipolar plug 93, the signal terminals 9-2, 9-3, 9-4 are in contact with the electrode 93-2. Therefore, in the flowchart of FIG. 6, the mono earphone unit 90 is recognized as the stereo headphone unit 80 by the block 219, and the CODEC 113 operates accordingly. Then, the output from the HP_L terminal of the CODEC 113 is output to the monaural earphone 91. Accordingly, the monaural earphone unit 90 can be automatically recognized and used when connected to the combo jack 9 without being distinguished from the stereo earphone unit 80. A two-plug headset is identified as a microphone or headphone in step 221 or step 227 of FIG. 6 when either a microphone or headphone plug is inserted into the combo jack.

  FIG. 5 shows an example in which the switches 107 and 109, the transistors 103 and 105, the control circuit 101, the identification signal generation circuit 111, and the like mounted on the audio controller are configured as independent devices different from the CODEC 113. In the present invention, the functions of these devices can be incorporated into the CODEC 113 to form a single semiconductor device. Further, the electrode of the plug 59 of the combo headset 50 is not limited to the arrangement shown in FIG. 3A, the drain terminal of the ECM 55 is connected to the electrode 59-3, and the electrode 59-4 is connected to the ECM 55. Even if the source terminal is connected, any one of the ECM unit 70 and the stereo earphone unit 80 can be identified. In this case, in the identification circuit 100, the bias power source Vcc1 is connected to the signal terminal 9-3, and the signal terminal 9-4 is connected to the ground E.

  A combo jack 9 may be inserted with a two-pole plug of a dynamic microphone. The electrode of the two-pole plug is connected to the coil similarly to the monaural earphone shown in FIG. Therefore, the identification circuit 100 cannot distinguish between the dynamic microphone and the stereo earphone unit 80. A dynamic microphone is not used by applying a voltage, and may cause a failure when a voltage is applied to the coil. However, the identification circuit 100 applies bias power to the signal terminals 9-2 and 9-4, and in the case of a two-pole jack, the signal terminals 9-2, 9-3, and 9-4 contact one electrode, That one electrode is brought to zero potential by the signal terminal 9-3, so that it does not disturb the dynamic microphone.

  The identification circuit 100 is advantageous in terms of cost and space because it does not need to measure the impedance of the audio device and can be realized with a simple circuit. Further, the identification circuit 100 can identify three types of audio devices, and further, four or more types of audio devices can be connected to the combo jack 9 for use.

  Although the present invention has been described with the specific embodiments shown in the drawings, the present invention is not limited to the embodiments shown in the drawings, and is known so far as long as the effects of the present invention are achieved. It goes without saying that any configuration can be adopted.

9 ... Combo jack 50 ... Combo headset 51 ... Left headphones 53 ... Right headphones 55 ... ECM
57, 75 ... Mute button 59 ... 4-pole plug 70 ... ECM unit 73, 85 ... 3-pole plug 80 ... Stereo earphone unit 90 ... Monaural earphone unit 93 ... 2-pole plug

Claims (10)

An apparatus for recognizing an audio device connected by a plug to an audio jack in which a first terminal, a second terminal, a third terminal, and a fourth terminal are arranged in order,
A switch connected between the bias power supply of the electret condenser microphone and the second terminal;
A ground connected to the third terminal;
A bias power supply for an electret condenser microphone connected to the fourth terminal;
A first potential detection circuit for detecting the potential of the fourth terminal;
A second potential detection circuit for detecting the potential of the first terminal;
When the first potential detection circuit does not detect a potential of a predetermined magnitude, the switch is turned on and when the second potential detection circuit detects a potential of a predetermined magnitude, it is connected to a three-pole plug And a control circuit for outputting a detection signal indicating the first audio device.   The recognition apparatus according to claim 1, wherein when the first potential detection circuit detects a potential having a predetermined magnitude, the control circuit is connected to a four-pole plug and outputs a detection signal indicating the second audio device. .   The recognition apparatus according to claim 2, wherein the control circuit maintains a detection signal indicating the second audio device until the four-pole plug is pulled out from the audio jack.   The control circuit detects a third audio device connected to a three-pole plug in the audio jack when the switch is turned on and the second potential detection circuit does not detect a potential of a predetermined magnitude. The recognition apparatus according to claim 1, which outputs a signal.   The recognition apparatus according to claim 4, wherein the control circuit turns off the switch in response to the second potential detection circuit not detecting a potential having a predetermined magnitude.   A portable computer equipped with the recognition device according to any one of claims 1 to 5. A method in which a recognition device recognizes an audio device connected by a plug to an audio jack in which a first terminal, a second terminal, a third terminal, and a fourth terminal are arranged in order,
Applying the bias voltage of the electret condenser microphone to the fourth terminal by the recognition device;
The recognition device detecting a potential of the fourth terminal;
Applying a bias voltage of an electret condenser microphone to the second terminal when the recognition device does not detect a potential of a predetermined magnitude at the fourth terminal;
The recognition device detecting a potential of the first terminal;
And a step of outputting a detection signal indicating the first audio device connected to the three-pole plug when a predetermined potential is detected at the first terminal.   8. The recognition method according to claim 7, further comprising a step of outputting a detection signal indicating a second audio device connected to a four-pole plug when a potential having a predetermined magnitude is detected at the fourth terminal.   9. The method according to claim 7, further comprising a step of outputting a detection signal indicating a third audio device connected to a three-pole plug when no potential of a predetermined magnitude is detected at the first terminal. Recognition method. A semiconductor device connectable to an audio jack in which a first terminal, a second terminal, a third terminal, and a fourth terminal are arranged in order,
An electret condenser microphone bias voltage application circuit for the fourth terminal;
A first potential detection circuit for detecting the potential of the fourth terminal;
A switch circuit for controlling application of an electret condenser microphone bias voltage to the second terminal;
A second potential detection circuit for detecting the potential of the first terminal;
When the first potential detection circuit does not detect a potential having a predetermined magnitude, the switch circuit is controlled to apply a bias voltage to the second terminal, and the second potential detection circuit has a predetermined magnitude. And a control circuit for controlling an internal device so as to operate corresponding to the electret condenser microphone connected to the three-pole plug when the potential of the first electrode is detected.

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