JP2008091255A - Input switchover apparatus, input switching method and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an input switching apparatus capable of being made compact, an input switchover method, and a program. <P>SOLUTION: A resistance is placed in between a signal input line connected to a connector terminal, corresponding to one plug terminal to which a predetermined input device is connected, among a plurality of connector terminals, disposed on a connector corresponding to a multipolar plug, and a voltage power supply line for supplying the input device with a voltage via the signal input line, and a detecting means for detecting whether to connect in the multipolar plug by the variations by voltage in the signal input line is connected to the signal input line. In addition, an opening switch is provided between a connecting point in the voltage power supply line side of the resistance and a voltage-adjusting resistance disposed on the voltage power supply line, and a control means for controlling the opening switch so as to close the opening switch, after the detection of the connection of the multipole plug by the detecting means is provided. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an input switching device, an input switching method, and a program, and is suitable for application to, for example, a music playback device.

  Conventionally, music playback devices equipped with a noise canceling function have been proposed. The earphone or headphone connected to the music playback device is equipped with a microphone that collects sound around the earphone or headphone as noise sound.

  The noise canceling function is turned on / off depending on when an earphone or headphone equipped with a microphone is connected to this music playback device and when a normal earphone or headphone not equipped with the microphone is connected. Or when a speaker is mounted on the music playback device and an earphone or a headphone equipped with a microphone is connected to the music playback device, and when a normal earphone or headphone without the microphone is installed The presence or absence of connection of an earphone or headphone may be detected, for example, when the output destination of an audio signal is switched depending on when it is connected.

As a device for detecting the presence or absence of connection of the earphone or the headphone, there is a connection detection system related to an F-type connector (see, for example, Patent Document 1).
JP 2006-164669 A

  By the way, in the connection detection system having such a configuration, the connection detection terminal is provided independently in the F-type connector, and the detection circuit corresponding to the detection terminal is provided in the main body. .

  The present invention has been made in view of the above points, and intends to propose an input switching device, an input switching method, and a program that can be miniaturized.

  In order to solve such a problem, the present invention is an input switching device, and corresponds to one plug terminal to which a predetermined input device is connected among a plurality of connector terminals arranged in a connector corresponding to a multipolar plug. A resistor is provided between the signal input line connected to the connector terminal and a voltage supply line for supplying a voltage to the input device via the signal input line, and a connection in the multipolar plug is caused by a voltage change in the signal input line. The detecting means for detecting the presence or absence of is connected to the signal input line. In addition, an open switch is provided between the connection point on the voltage supply line side of the resistor and the voltage adjustment resistor arranged on the voltage supply line, and after the connection of the multipolar plug is detected by the detection means, Control means for controlling the open switch is provided so as to close the open switch.

  Further, the present invention is an input switching method, and is connected to a connector terminal corresponding to one plug terminal to which a predetermined input device is connected among a plurality of connector terminals arranged in a connector corresponding to a multipolar plug. The voltage disposed on the voltage supply line for supplying a voltage to the input device through the signal input line after detecting a voltage change in the signal input line and detecting a connection in the multipolar plug due to the voltage change. The open switch provided between the adjusting resistor and the connection point on the voltage supply line side in the resistor between the voltage supply line and the signal input line is closed.

  Furthermore, the present invention is a program that is a signal connected to a connector terminal corresponding to one plug terminal to which a predetermined input device is connected among a plurality of connector terminals arranged in a connector corresponding to a multipolar plug. Waiting for notification that the connection in the multipolar plug has been detected from the detection means that detects the presence or absence of the connection in the multipolar plug due to the voltage change in the input line, and input via the signal input line after receiving the notification An open switch provided between the voltage adjusting resistor arranged on the voltage supply line for supplying a voltage to the device and a connection point on the voltage supply line side in the resistor between the voltage supply line and the signal input line. The closing was executed for the computer.

  In the present invention, when the open switch is not closed, the presence or absence of connection of the multipolar plug is detected by the voltage change of the voltage supplied from the voltage supply line to the signal input line through the resistor, while the open switch is closed. In this case, the voltage is supplied to the input device as a reference voltage by dividing the resistance between the signal input line and the voltage supply line and the adjustment resistor, and an input signal supplied from the input device is input. Will be able to. That is, the signal input line can be shared as a line for detecting the presence or absence of connection of the multipolar plug. Therefore, in the present invention, it is possible to detect the presence / absence of connection of the multipolar plug without separately providing a terminal for independent connection detection in the multipolar plug, and thus the input switching device, the input switching method, and the like that can be miniaturized. A program can be realized.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

(1) Appearance Configuration of Portable Music Player FIG. 1 shows an appearance configuration of a portable music player (hereinafter referred to as a portable music player) according to the present embodiment. The portable music player 1 is formed in a substantially rectangular parallelepiped shape that is rounded, and is large enough to be held with one hand.

  Various operation buttons, a display unit DP, and the like are provided on the surface of the portable music player 1. A jack JAK is provided at a predetermined position of the portable music player 1, and the jack JAK is routed from earphones EP1 and EP2 equipped with microphones (hereinafter referred to as earphones with microphones). A plug PLG provided at the tip of the connection cord CD is connected.

(2) Configuration of Plug and Jack This plug PLG and jack JAK are formed in correspondence with the standard mini-plug standard. The configuration of the plug PLG and jack JAK will be described below.

(2-1) Configuration of Plug As shown in FIGS. 2 to 6, the plug PLG includes a first conductor 11, a first insulator 12, a second conductor 13, a second insulator 14, 3 conductor 15, third insulator 16, fourth conductor 17, fourth insulator 18, and fifth conductor 19.

  The first conductor 11, the second conductor 13, the third conductor 15, the fourth conductor 17 and the fifth conductor 19 are all formed of a highly conductive metal material, and the first insulator 12, The second insulator 14, the third insulator 16, and the fourth insulator 18 are all formed of a non-conductive material such as a resin material.

  In this embodiment, the first conductor 11 is assigned as the terminal of the left (or right) speaker, and the second conductor 13 is assigned as the terminal of the right (or left) speaker. The third conductor 15 is assigned as a ground terminal. Further, the fourth conductor 17 is assigned as the terminal of the left (or right) microphone, and the fifth conductor 18 is assigned as the terminal of the right (or left) microphone.

  The first conductor 11 is formed in a substantially round shaft shape, and has a large-diameter electrode portion 11a and a small-diameter fitting portion 11b. The first conductor 11 is provided with a flange portion 11c projecting outward between the electrode portion 11a and the fitting portion 11b, and a cord is connected to the end portion of the fitting portion 11b opposite to the flange portion 11c. A portion 11d is provided.

  The outer peripheral surface of the electrode portion 11a is formed as an inclined surface 11e that is inclined so as to be displaced toward the center as it approaches the fitting portion 11b. The fitting portion 11b is longer in the axial direction than the electrode portion 11a. The cord connecting portion 11d has a diameter smaller than that of the electrode portion 11a and larger than that of the fitting portion 11b.

  The first insulator 12 is formed in a substantially cylindrical shape, and one end portion in the axial direction is provided as a large diameter portion 12a having a larger outer diameter than the other portion, and a portion other than the large diameter portion 12a is provided as a small diameter portion 12b. It has been. The large diameter part 12a is formed thicker than the small diameter part 12b. The end of the small-diameter portion 12b opposite to the large-diameter portion 12a is a protruding portion 12c that slightly protrudes outward, and a shallow fitting recess on the outer surface side between the large-diameter portion 12a and the protruding portion 12c. 12d is formed.

  The first insulator 12 is externally fitted to the fitting portion 11 b of the first conductor 11. In the state in which the first insulator 12 is externally fitted to the first conductor 11, the outer peripheral surface of the large-diameter portion 12a coincides with the outer peripheral surface of the flange portion 11c in the radial direction. The first conductor 11 has an electrode portion 11a, a flange portion 11c, and a cord connection portion 11d exposed.

  The second conductor 13 is formed in a substantially cylindrical shape, and has a large-diameter electrode portion 13a and a small-diameter fitting portion 13b. The first conductor 13 is provided with a connecting portion 13c formed in a substantially annular shape for connecting the electrode portion 13a and the fitting portion 13b, and the end portion of the fitting portion 13b opposite to the connecting portion 13c is a cord. It is provided as a connecting portion 13d.

  The second conductor 13 is externally fitted to the first insulator 12. In a state where the second conductor 13 is externally fitted to the first insulator 12, the electrode portion 13a is coupled to a portion excluding one end portion of the large diameter portion 12a, and the fitting portion 13b and the connecting portion 13c are fitted to the fitting recess. 12d, the outer peripheral surface of the fitting portion 13b is aligned with the outer peripheral surface of the overhang portion 12c in the radial direction. Therefore, the second insulator 12 has a part of the large diameter portion 12a and the overhang portion 12c exposed.

  The second insulator 14 is formed in a substantially cylindrical shape, and one end portion in the axial direction is provided as a large diameter portion 14a having a larger outer diameter than the other portion, and a portion other than the large diameter portion 14a is provided as a small diameter portion 14b. It has been. The large diameter portion 14a is formed thicker than the small diameter portion 14b. The end of the small-diameter portion 14b opposite to the large-diameter portion 14a is a protruding portion 14c slightly protruding outward, and a shallow fitting recess on the outer surface side between the large-diameter portion 14a and the protruding portion 14c. 14d is formed.

  The second insulator 14 is externally fitted to the fitting portion 13 b of the second conductor 13. When the second insulator 14 is fitted on the second conductor 13, the outer peripheral surface of the large-diameter portion 14a is aligned with the outer peripheral surface of the electrode portion 13a in the radial direction. The second conductor 13 has the electrode portion 13a and the cord connecting portion 13d exposed.

  The third conductor 15 is formed in a substantially cylindrical shape, and has a large-diameter electrode portion 15a and a small-diameter fitting portion 15b. The first conductor 15 is provided with a connecting portion 15c formed in a substantially annular shape for connecting the electrode portion 15a and the fitting portion 15b, and the end portion of the fitting portion 15b opposite to the connecting portion 15c is a cord. It is provided as a connecting portion 15d.

  The third conductor 15 is externally fitted to the second insulator 14. In a state where the third conductor 15 is externally fitted to the second insulator 14, the third conductor 15 is coupled to the fitting recess 14 d, and the outer peripheral surface of the electrode portion 15 a is aligned with the outer peripheral surface of the large-diameter portion 14 a in the radial direction. The outer peripheral surface of the joint portion 15b is aligned with the outer peripheral surface of the overhang portion 14c in the radial direction. Therefore, the second insulator 14 has the large diameter portion 14a and the overhang portion 14c exposed.

  The third insulator 16 is formed in a substantially cylindrical shape, and one end portion in the axial direction is provided as a large diameter portion 16a having a large outer diameter, and a portion continuous with the large diameter portion 16a in the axial direction is provided as a small diameter portion 16b. The other end portion in the axial direction is provided as a protruding portion 16c having a larger outer diameter than the small diameter portion 16b. The large diameter portion 16a and the overhang portion 16c are formed thicker than the small diameter portion 16b. The third insulator 16 is formed with a shallow fitting recess 16d on the outer surface side between the large diameter portion 16a and the overhang portion 16c.

  The third insulator 16 is externally fitted to the fitting portion 15 b of the third conductor 15. In a state in which the third insulator 16 is externally fitted to the third conductor 15, the outer peripheral surfaces of the large diameter portion 16a and the overhang portion 16c are aligned with the outer peripheral surface of the electrode portion 15a in the radial direction. The third conductor 15 has the electrode portion 15a and the cord connecting portion 15d exposed.

  The fourth conductor 17 is formed in a substantially cylindrical shape, and includes an electrode portion 17a and an annular protrusion 17b provided to project outward on the outer peripheral surface of the central portion in the axial direction of the electrode portion 17a. A part of the electrode portion 17a is provided as a cord connecting portion 17c.

  The fourth conductor 17 is externally fitted in the fitting recess 16 d of the third insulator 16. When the fourth conductor 17 is fitted on the third insulator 16, the outer peripheral surface of the electrode portion 17a is aligned with the outer peripheral surface of the large-diameter portion 16a and the outer peripheral surface of the overhang portion 16c in the radial direction. Yes. Therefore, the third insulator 16 has the large diameter portion 16a and the overhang portion 16c exposed.

  The fourth insulator 18 is formed by integrally forming a conductor attaching portion 20 and an extending portion 21 (see FIGS. 4 and 6).

  The conductor attachment portion 20 is formed long in one direction. As shown in FIG. 7, the main body portion 20a and projecting portions 20b and 20b projecting from one end in the longitudinal direction of the main body portion 20a to the opposite sides in the short direction. It consists of. A conductor mounting groove 20c extending in the longitudinal direction is formed in the main body portion 20a, and a fitting groove 20d extending in the short direction is formed on the surface opposite to the surface on which the conductor mounting groove 20c is formed. The extending portion 21 protrudes from one end surface in the longitudinal direction of the conductor attachment portion 20 in a direction orthogonal to the protruding direction of the protruding portions 20b and 20b.

  The fourth insulator 18 is attached to a part of the outer peripheral surface of the portion where the conductor attachment portion 20 extends from the large-diameter portion 14a to the overhanging portion 14c of the third insulator 14, and the extending portion 21 is the third portion. Are attached to a part of the outer peripheral surface of the portion extending from the cord connecting portion 15d of the conductor 15 to the overhanging portion 12c of the first insulator 12. Thus, in the state in which the fourth insulator 18 is attached, the protrusion 17b of the fourth conductor 17 is fitted into the fitting groove 20d, and the conductor attaching portion 20 is positioned on the outer peripheral side from the extending portion 21. Has been.

  The fifth conductor 19 is formed in a plate shape that is long in one direction, and has regulating protrusions 19a and 19a that protrude in opposite directions to each other in the middle in the longitudinal direction. The fifth conductor 19 has one side as an insertion portion 19b and the other side as a cord connection portion 19c with respect to the regulation protrusions 19a and 19a. A connecting protrusion 19d protruding in the thickness direction is provided at the end of the insertion portion 19b opposite to the cord connecting portion 19c.

  The fifth conductor 19 is attached to the fourth insulator 18 by inserting the insertion portion 19b into the conductor attachment groove 20c (see FIG. 3). In the state where the fifth conductor 19 is attached to the fourth insulator 18, the regulating protrusions 19 a and 19 a are in contact with one end surface of the main body 20 a, and the cord connecting portion 19 c is separated from the extending portion 21 toward the outer peripheral side. (See FIG. 4).

  In the plug 5 configured as described above, as shown in FIGS. 5 and 6, the cord connecting portion 11 d of the first conductor 11, the cord connecting portion 13 d of the second conductor 13, and the third conductor 15 One end of the corresponding connection cord CDa, CDb, CDc, CDd, CDe is connected to the cord connecting portion 15d, the cord connecting portion 17c of the fourth conductor 17 and the cord connecting portion 19c of the fifth conductor 19 by soldering, for example. Each is connected.

  The other ends of these connection codes CDa, CDb, CDc, CDd, and CDe are the speaker SK1 (FIG. 1) of the earphone EP1 with the microphone (FIG. 1), the speaker SK2 (FIG. 1) of the earphone with the microphone EP2 (FIG. 1), and the microphone. A ground terminal (not shown) in the attached earphones ER1 and ER2, a microphone MC1 (FIG. 1) of the earphone EP1 with the microphone (FIG. 1), and a microphone MC2 (FIG. 1) of the earphone EP2 with the microphone (FIG. 1) are connected. .

  Incidentally, these connection cords CDa, CDb, CDc, CDd, and CDe are covered by the cover 10 from the protrusion 17b of the fourth conductor 17 to the cord connection portion 11d of the first conductor 11, and the cord connection portion. 11d, 13d, 15d, 17c, and 19c are closed (see FIG. 2).

(2-2) Configuration of Jack Next, the configuration of the jack JAK corresponding to the plug PLG will be described. As shown in FIG. 8, the jack JAK has a casing 24 and is attached to a predetermined position of the portable music player 1.

  The casing 24 is formed with a plug insertion hole 24a opened on one side. Five terminal pieces 25 protrude from the end of the jack JAK opposite to the opening of the plug insertion hole 24a. The terminal piece 25 is connected to an electronic circuit inside the portable music player 1.

  As shown in FIGS. 9 and 10, the housing 24 has a first connection terminal 26, a second connection terminal 27, a third connection terminal 28, a fourth connection terminal 29, and a fifth connection terminal. A connection terminal 30 is arranged.

  The first connecting terminal 26 (see FIG. 9) includes a base portion 26a disposed along the inner surface of the jack JAK, and a base end portion 26b that is folded back from the base portion 26a and extends away from the plug insertion hole 24a. And a leaf spring portion 26c that is continuous with the base end portion 26b and bent in a direction away from the base portion 26a with respect to the base end portion 26b, and a distal end portion of the leaf spring portion 26c serves as a connection portion 26d. Is provided.

  The second connection terminal 27 (see FIG. 10) includes a base end portion 27a arranged in parallel with the inner surface of the jack JAK, and an inner surface of the jack JAK that is continuous with the base end portion 27a and is connected to the base end portion 27a. A leaf spring portion 27b bent in a direction away from the front end, and a distal end portion of the leaf spring portion 27b is provided as a connection portion 27c. The connecting portion 27 c is located closer to the plug insertion hole 24 a than the connecting portion 26 d of the first connecting terminal 26.

  The third connection terminal 28 (see FIG. 9) has a base end portion 28a disposed along the inner surface of the jack JAK, and is spaced from the inner surface of the jack JAK with respect to the base end portion 28a. And a distal end portion of the leaf spring portion 28b is provided as a connection portion 28c. The connection portion 28 c is located closer to the plug insertion hole 24 a than the connection portion 27 c of the second connection terminal 27.

  The fourth connection terminal 29 (see FIGS. 9 and 10) includes a base end portion 29a disposed along the inner surface of the jack JAK, and a jack end of the jack JAK connected to the base end portion 29a. A leaf spring portion 29b bent in a direction away from the inner surface, and a tip portion of the leaf spring portion 29b is provided as a connection portion 29c. The connection portion 29c is located closer to the plug insertion hole 24a than the connection portion 28c of the third connection terminal 28, and is located immediately inside the opening of the plug insertion hole 24a.

  The fifth connection terminal 30 (see FIG. 10) has a base end portion 30a disposed along the inner surface of the jack JAK, and is spaced from the inner surface of the jack JAK with respect to the base end portion 30a. The leaf spring portion 30b is bent in the direction to be bent, and the distal end portion of the leaf spring portion 30b is provided as a connection portion 30c. The connection part 30c is located immediately inside the opening of the plug insertion hole 24a.

  A stopper wall 31 is provided inside the jack JAK (see FIG. 10). The stopper wall 31 is located on the opposite side to the inner surface of the jack JAK with the leaf spring portion 30b of the fifth connection terminal 30 interposed therebetween.

  A holding insulating member 32 is provided inside the jack JAK (see FIGS. 9 and 10). The holding insulating member 32 is provided at the end opposite to the opening of the plug insertion hole 24a.

  The first connection terminal 26, the second connection terminal 27, the third connection terminal 28, the fourth connection terminal 29, and the fifth connection terminal 30 are each partially embedded in the holding insulating member 32 and held. The terminal piece 25 is continuously connected to each other. Accordingly, the first connection terminal 26, the second connection terminal 27, the third connection terminal 28, the fourth connection terminal 29, and the fifth connection terminal 30 are connected to the portable music player via the terminal pieces 25, respectively. 1 is connected to an internal circuit.

(2-3) Connection state of plug and jack When the plug PLG is inserted into the plug insertion hole 24a of this jack JAK, as shown in FIGS. 11 and 12, the electrode portion 11a of the first conductor 11, the second The electrode portion 13a of the third conductor 13, the electrode portion 15a of the third conductor 15, the electrode portion 17a of the fourth conductor 17, and the connecting projection 19a of the fifth conductor 19 correspond to the corresponding left (or right) speaker. A connection portion 26d of the first connection terminal 26, a connection portion 27c of the second connection terminal 27 for the right (or left) speaker, a connection portion 28c of the third connection terminal 28 for the ground, and the left (or right). The connection portion 29c of the fourth connection terminal 29 for the microphone and the connection portion 30c of the fifth connection terminal 30 for the right (or left) microphone are connected.

  At this time, the plug PLG has a position where the projection 17b of the fourth conductor 17 contacts the outer opening edge of the plug insertion hole 24a in the jack JAK and one end surface of the insertion portion 19b of the fifth conductor 19 contacts the stopper wall 31. Until the jack JAK is positioned in the insertion direction.

  The connection portions 26d, 27c, 28c, 29c, and 30c are elastically deformed against the spring force with respect to the base end portions 26b, 27a, 28a, 29a, and 30a, respectively, and the electrode portions 11a, 13a, and 15a, The electrodes 17a and the connection projections 19a are connected in a pressed state.

(3) Circuit Configuration of Portable Music Player (3-1) Circuit Configuration of Entire Portable Music Player Next, as the circuit configuration of the portable music player 1, the entire circuit configuration of the portable music player 1 will be described. As shown in FIG. 13, the portable music player 1 has an operation unit 51, a data storage medium 52, a plug detection unit 53, a display unit DP, and a signal with respect to a control unit 50 that controls the entire portable music player 1. It is configured by connecting the processing unit 54.

  The control unit 50 is a microcomputer including a CPU (Central Processing Unit), a ROM (Read Only Memory) storing various programs and setting data, and a RAM (Random Access Memory) used as a work memory of the CPU. Composed.

  The control unit 50 controls the data storage medium 52, the display unit DP, and the signal processing unit 54 based on the control data given from the operation unit 51 and the setting data stored in the ROM according to the program stored in the ROM. Control as appropriate.

  The operation unit 51 generates control data corresponding to the operation of various operation buttons provided on the housing surface of the portable music player 1 and sends it to the control unit 50.

  The data storage medium 52 is, for example, an EEPROM (Electrically Erasable Programmable Read Only Memory), and the data storage medium 12 stores various data such as a digital audio signal D1.

  The display unit DP is provided, for example, as a FL (Fluorescent Lamp) tube on the housing surface of the portable music player 1 (see FIG. 1). Based on the display data generated by the control unit 50, for example, the playback content is displayed. The state of the playback mode currently specified, whether or not a noise-cancelling earphone (or headphones) is connected, etc. are displayed in characters and graphics.

  An example of a display screen displayed on the display unit DP is shown in FIG. At the left end of the display screen, an image IM related to the current reproduction target or a sample image (not shown) stored in the ROM as setting data is displayed. The title name of the current playback target is displayed in the upper center of the display screen, the artist name of the current playback target is displayed in the middle middle, and the playback time of the current playback target is displayed in the lower center. Further, at the lower right corner of the display screen, the current remaining amount with respect to the battery capacity is displayed as a graphic simulating the battery.

  On the other hand, on the left side of the figure simulating the battery, a figure AC1 representing the shuffle playback mode and a figure AC2 representing the repeat reproduction mode are shown, and on the upper side of the figure simulating the battery, the figure AC3 representing the surround mode and its number. Is displayed when the mode is specified.

  On the other hand, a graphic AC4 indicating that a noise canceling earphone (or headphones) is connected to the upper side of the graphic AC3 is a character other than the graphic AC4 when the earphone (or headphones) is connected. And a color different from that of the figure. Therefore, in this display screen example, it is possible to pay attention to the fact that noise canceling compatible earphones (or headphones) are connected.

  The plug detection unit 53 detects the presence or absence of connection in the plug PLG of an earphone (or headphone) that supports jack noise canceling. Specifically, an audio signal supplied from the microphone MC1 of the microphone-equipped earphone MP1 among the connection terminals 26, 27, 28, 29, and 30 (for example, FIGS. 9 and 10) arranged in the jack JAK is input. The presence or absence of connection in the plug PLG of the jack noise canceling earphone (or headphone) by the voltage change of the signal line (hereinafter referred to as the audio input line) connected to the terminal (microphone input terminal) 29 for To detect.

  In addition, when a standard mini plug of an earphone (or headphone) that does not support noise canceling, that is, an earphone (or headphone) that is not equipped with a microphone, is connected, each connection terminal 26, 27, 28 arranged on the jack JAK is connected. 29, 30 (for example, FIGS. 9 and 10), only the left and right channel speaker connection terminals 26 and 27 and the ground connection terminal 28 are connected to the plug-side terminal.

  In this case, since the voltage change does not occur in the audio input line LN1, the plug detection unit 53 detects that the plug PLG of the earphone (or headphone) that supports jack noise canceling is not connected.

  Further, when the plug detection unit 53 detects the connection of the plug PLG of the earphone (or headphone) compatible with jack noise canceling, the plug detection unit 53 notifies the control unit 50 that the earphone (or headphone) is connected. Has been made.

  A digital audio signal D1 reproduced from the data storage medium 12 is input to a DSP (Digital Signal Processor) 54A of the signal processing unit 54. When a noise canceling-compatible earphone (or headphone) plug PLG is connected to the jack JAK, the first filter coefficient representing the frequency characteristic corresponding to the noise canceling mode is input as setting data. When the plug PLG is not connected, the second filter coefficient representing the frequency characteristic not corresponding to the noise canceling mode is input as setting data.

  The DSP 54A performs a filtering process on the digital audio signal D1 based on the first or second filter coefficient input as setting data. Incidentally, when the digital audio signal D1 is compressed, the DSP 54A also performs an expansion process according to the compression method.

  Further, the DSP 54A performs D / A (Digital / Analog) conversion processing after the filter processing, and sends the left and right channel analog audio signals S1 obtained as a result to the synthesizing unit 54C.

  On the other hand, when a noise canceling signal generation unit 54B of the signal processing unit 54 is connected with a plug PLG of a noise canceling earphone (or headphone) to the jack JAK, a microphone is connected via the plug PLG. Left and right channel audio signals S2 are input from the microphones MC1 and MC2 (FIG. 1) of the attached earphones EP1 and EP2.

  The noise canceling signal generation unit 54B generates audio signals having phases opposite to those of the input left and right channel audio signals S2, and sends these to the synthesis unit 54C as noise canceling signals S3.

  The synthesizing unit 54C synthesizes the left and right channel analog audio signals S1 supplied from the DSP 54A and the left and right channel noise canceling signals S3 supplied from the noise canceling signal generating unit 54B in units of corresponding channels. The channel synthesis result is sent to the signal amplifier 54D as an audio output signal S4.

  Incidentally, when the noise canceling signal S3 is not supplied from the noise canceling signal generation unit 54B, that is, when a plug of an earphone (or headphones) that does not support noise canceling is connected to the jack JAK, the DSP 54A The supplied analog audio signal S1 is sent to the signal amplifier 54D as an audio output signal S4.

  The signal amplifying unit 54D amplifies the audio output signal S4 input from the synthesizing unit 54C based on the volume control data supplied from the operation unit 11, and then amplifies the audio output signal S4 corresponding to the jack JAK (for example, FIG. 9). And FIG. 10).

(3-2) Circuit Configuration of Plug Detection Unit Next, a circuit configuration of the plug detection unit 53 will be described. As shown in FIG. 15, the plug detection unit 53 includes a resistor 53A, a voltage detection circuit 53B, and a switch element 53C.

  The resistor 53A includes an audio input line LN1 connected to a terminal (microphone input terminal) 29 for inputting an audio signal supplied from the microphone MC1 of the earphone MP1 with microphone, and a voltage connected to the audio input line LN1. It is provided between the supply line LN2.

  The resistor 53A is connected in parallel to the adjustment resistor RX arranged on the voltage supply line LN2 for adjusting the reference voltage for the microphone MC1.

  The voltage detection circuit 53B is connected to the voice input line LN1, and monitors the voltage of the voice input line LN1.

  The switch element 53C is provided on the voltage supply line LN2 and between the connection point P1 of the resistor 53A and the adjustment resistor RX. The switch element 53C is in an open state in a mode for detecting the presence or absence of connection in the plug PLG of an earphone (or headphone) compatible with noise canceling (hereinafter referred to as a detection mode), and the sound is output from the microphone MC1. In the case of a signal input mode (hereinafter referred to as a voice input mode), the closed state is set.

  Here, when the switch element 53C is in the open state, that is, in the detection mode state, when the plug PLG of the earphone (or headphone) compatible with noise canceling is not connected, the terminal (microphone input terminal) 29 becomes an open end. For this reason, the voltage supplied from the voltage source in the portable music player 1 is supplied from the connection point P1 to the voltage detection circuit 53B via the resistor 53A.

  On the other hand, when the plug PLG of the earphone (or headphone) compatible with noise canceling is connected in the detection mode state, the terminal (microphone input terminal) 29 is connected to the microphone MC1. For this reason, the voltage supplied from the voltage source in the portable music player 1 is supplied from the connection point P1 to the ground via the resistor 53A and the microphone MC1. Therefore, in this case, the voltage supplied to the voltage detection circuit 53B is stepped down.

  In the voltage detection circuit 53B, a high level and a low level are set as detection thresholds for this voltage change. When the voltage supplied to the voltage detection circuit 53B exceeds the high level, noise canceling is supported. It is detected that the plug PLG of the earphone (or headphone) is not connected. On the other hand, when the level is below the low level, it is detected that the plug PLG of the earphone (or headphone) compatible with noise canceling is connected.

  The voltage detection circuit 53B is connected when a noise canceling-compatible earphone (or headphone) plug PLG is connected, that is, when the voltage supplied to the voltage detection circuit 53B is lower than the low level. The notification data D2 (FIG. 13) is raised (or lowered) to turn it on, thereby notifying the controller 50 that the plug PLG is connected.

  In this embodiment, the resistance value of the resistor 53A is equal to or greater than the product of the resistance value of the microphone MC1 and the level ratio between the high level and the low level set as the voltage change detection threshold for the voltage detection circuit 53B. In addition, the value is selected within a range that is equal to or less than a division value between the resistance value in the voltage detection circuit 53B and the level ratio. In practice, the resistance value of the resistor 53A in this embodiment is 100 [kΩ]. Incidentally, the adjustment resistor RX is set to 3 [kΩ].

  Therefore, the plug detection unit 53 transmits an audio signal from the microphone MC1 to the audio input line LN1 via the terminal (microphone input terminal) 29 in a state where the plug PLG of the earphone (or headphone) compatible with noise canceling is connected. When the signal is input, it is possible to prevent a situation in which the voltage detection circuit 53B erroneously detects that the plug PLG is not connected due to the voltage fluctuation of the sound input line LN1 based on the sound signal. ing.

  In addition, the plug detection unit 53 detects noise when noise is input via the terminal (microphone input terminal) 29 in a state where the plug PLG of the noise canceling earphone (or headphone) is not connected. It is possible to prevent a situation in which the voltage detection circuit 53B erroneously detects that the plug PLG is connected due to the voltage fluctuation of the voice input line LN1 based on it.

  On the other hand, when the switch element 53C is in the closed state, that is, in the voice input mode, the voltage supplied from the voltage source in the portable music player 1 is divided by the resistor 53A and the adjustment resistor RX to be the reference voltage for the microphone MC1. Thus, the audio signal input from the microphone MC1 via the terminal (microphone input terminal) 29 is sent to the noise canceling signal generation unit 54B via the audio input line LN1.

  As described above, the plug detection unit 53 can use the audio input line LN1 as a line for detecting the presence or absence of connection in the plug PLG of the earphone (or headphone) compatible with noise canceling in the detection mode. Yes.

(3-3) Mode Switching Process The mode switching between the above-described detection mode and voice input mode is executed by the control unit 50. Here, the mode switching processing procedure by the control unit 50 will be described with reference to the flowchart shown in FIG.

  That is, when the power is turned on, the control unit 50 starts this mode switching processing procedure RT, and in step SP1, by switching the switch element 53C (FIG. 15) of the plug detection unit 53 to the open state, the voice input line LN1 (FIG. 15) is used as a line for detecting the presence or absence of connection in the plug PLG of the noise canceling earphone (or headphone), and the plug detection unit 53 is made to detect the plug PLG (detection mode).

  Thereafter, the control unit 50 proceeds to step SP2 and waits for a notification of connection of the plug PLG from the voltage detection circuit 53B (FIG. 15) of the plug detection unit 53.

  When the connection notification data D2 is received, the control unit 50 proceeds to the next step SP3 and, as shown in FIG. 14, the noise canceling-compatible earphone (or the noise canceling earphone (or the display unit DP) as shown in FIG. 14). The graphic AC4 indicating that the headphones are connected is displayed in a color different from that of the characters and graphics other than the graphic AC4, so that the earphone (or headphones) compatible with noise canceling is connected to the user. Focus on the situation.

  In step SP4, the control unit 50 waits for a playback command for the digital audio signal D1 stored in the data storage medium 52 from the operation unit 51 (FIG. 13). Proceeding to step SP5, the switch element 53C (FIG. 15) of the plug detection unit 53 is switched to the open state, thereby starting the input of the audio signal from the audio input line LN1 (audio input mode). In this case, the detection process by the plug detection unit 53 is stopped.

  Thereafter, the control unit 50 proceeds to step SP6, and sets the second filter coefficient (filter coefficient having a frequency characteristic not corresponding to the noise canceling mode) initially set for the DSP 54A (FIG. 13) to the first. The filter coefficient (filter coefficient having frequency characteristics corresponding to the noise canceling mode) is reset, and this mode switching processing procedure RT is terminated.

  In this way, the control unit 50 can switch the mode from the detection mode to the voice input mode.

(4) Operation and Effect According to this Embodiment In the above configuration, the portable music player 1 includes a plurality of connector terminals 26 arranged on the jack JAK corresponding to the multipolar plug PLG, as shown in FIG. 27, 28, 29, 30 (for example, FIG. 9 and FIG. 10), the audio input line LN1 connected to the connector terminal 29 corresponding to one plug terminal to which the microphone MC1 is connected, and the audio input line LN1 A resistor 53A is provided between the power supply line LN2 and the voltage supply line LN2 for supplying a voltage to the microphone MC1.

  Further, in this portable music player 1, a voltage detection circuit 53B that detects the presence or absence of connection in the plug PLG of a noise canceling earphone (or headphones) due to a voltage change in the audio input line LN1 is connected to the audio input line LN1. In addition to being connected, a switch 53C is provided between a connection point P1 of the resistor 53A on the voltage supply line LN2 side and an adjustment resistor RX arranged on the voltage supply line LN2.

  The portable music player 1 receives a notification from the voltage detection circuit 53B that the plug PLG of the noise canceling earphone (or headphone) is connected, and the switch 53C until a playback command is received from the operation unit 51. Keep it closed.

  Therefore, in the portable music player 1, when the switch is open, the voltage detection circuit 53B causes the voltage of the multipolar plug PLG to be changed by the voltage change of the voltage supplied from the voltage supply line LN2 to the audio input line LN1 through the resistor 53A. The presence or absence of connection can be detected.

  On the other hand, when the switch is in the closed state, the portable music player 1 supplies the voltage supplied from the voltage supply line LN2 to the microphone MC1 as a reference voltage by dividing the resistance 53A and the adjustment resistor RX, and the microphone MC1. The audio signal supplied from can be input.

  That is, the portable music player 1 can share the voltage supply line LN2 as a line for detecting the presence / absence of connection in the plug PLG of the earphone (or headphone) compatible with noise canceling.

  According to the above configuration, the voltage supply line LN2 can be shared as a line for detecting the presence / absence of connection in the plug PLG of the noise canceling earphone (or headphone), thereby providing an independent connection detection terminal. Therefore, it is possible to detect the plug PLG without providing a separate multipolar plug, thus realizing a portable music player 1 that can be miniaturized.

(5) Other Embodiments In the above-described embodiment, the case where the plug PLG and the jack JAK of the standard mini-plug standard are adopted has been described. However, the present invention is not limited to this, and other than this standard. Pin plugs and pin jacks may be employed, and connectors other than the pin type may be employed.

  Note that the assignment of each terminal in the plug PLG is left (or right) speaker, right (or left) speaker, ground, left (or right) microphone, and right (or left) microphone from the front end side (for example, 2), the present invention is not limited to this, and other allocation modes may be used. Incidentally, the same applies to the assignment of each terminal in the jack PLG.

  Further, in the above-described embodiment, when there is a notification that the plug PLG of the earphone (or headphone) compatible with noise canceling is connected and a reproduction command is received from the operation unit 51, the switch 53C (FIG. 15). ) Has been described. However, the present invention is not limited to this, and may be closed when the notification is received. In this way, even if the plug PLG is connected during reproduction, the reproduced sound after noise cancellation can be quickly output to the corresponding terminal of the plug PLG.

  In this case, as in the above-described embodiment, of the connector terminals 29 and 30 corresponding to the left and right microphones arranged in the jack JAK, the one closer to the plug insertion hole 24a (FIG. 8) of the jack JAK. If the presence or absence of connection in the plug PLG of the noise canceling earphone (or headphone) is detected by the voltage change of the audio input line LN1 connected to the arranged terminal 29, the plug insertion hole 24a (FIG. 8). This is more useful because it can be detected faster than in the case of detecting from the voltage change of the voice input line connected to the terminal 30 arranged farther away.

  Further, in the above-described embodiment, the case where the voltage change of the audio input line connected to the terminal 29 corresponding to the one plug terminal 17 to which the microphone MC1 is connected has been described. For example, the voltage change of the video input line connected to the terminal corresponding to one plug terminal to which the camera is connected may be monitored. In short, the present invention can be applied to any signal input line connected to a connector terminal corresponding to one plug terminal to which an input device is connected.

  Further, in the above-described embodiment, the case where the control unit 50 expands the program stored in the ROM on the RAM and executes the mode switching process (FIG. 16) according to the program has been described. The invention is not limited to this, and mode switching processing may be executed in accordance with a program installed from a recording medium such as a CD (Compact Disc), a DVD (Digital Versatile Disc), or a semiconductor memory, or a program downloaded from the Internet.

  Further, in the above-described embodiment, the case where the portable music player 1 is applied has been described. However, the present invention is not limited to this, and for example, a DVD player, an MD (Mini Disk) player, a CD player, a digital camera Various other devices having a connector corresponding to a plug having an input device such as a mobile phone, a PDA (Personal Digital Assistants), a video camera, or a television receiver can be applied.

  The present invention is applicable to an apparatus having a connector corresponding to a plug having an input device.

It is a basic diagram which shows the external appearance structure of a portable music player. It is an expansion perspective view of a plug. It is an enlarged side view of a plug. FIG. 4 is an enlarged side view of the plug shown in a state viewed from a direction different from FIG. It is an expanded sectional view of a plug. It is an expanded sectional view of the plug shown in the state seen from the direction different from FIG. It is an expansion perspective view which shows a 4th insulator and a 5th conductor. It is an expansion perspective view of a jack. It is sectional drawing which follows the IX-IX line of FIG. It is sectional drawing which follows the XX line of FIG. It is an expanded sectional view showing the state where the plug was connected to the jack. FIG. 12 is an enlarged cross-sectional view showing a state in which the plug is connected to the jack in a state seen from a direction different from FIG. 11. It is a block diagram which shows the circuit structure of a portable music player. It is a basic diagram which shows the example of a display screen. It is a basic diagram which shows the structure of a plug detection part. It is a flowchart which shows a mode switching process procedure.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Portable music player, 50 ... Control part, 51 ... Operation part, 52 ... Data storage part, 53 ... Plug detection part, 53A ... Resistance, 53B ... Voltage detection circuit, 53C ... Switch element 54 ... Signal processing unit 54A ... DSP 54B ... Noise canceling signal generation unit 54C ... Synthesis unit 54D ... Signal amplification unit DP ... Display unit AC1-AC4 ... Figure, EP1 EP2: Earphone with microphone, MC1, MC2 ... Microphone, SK1, SK2 ... Speaker, JAK ... Jack, PLG ... Plug, RT1 ... Mode switching processing procedure.

Claims (7)

Among a plurality of connector terminals arranged in a connector corresponding to a multipolar plug, a signal input line connected to a connector terminal corresponding to one plug terminal to which a predetermined input device is connected, and the signal input line A resistor provided between a voltage supply line for supplying a voltage to the input device,
Detecting means connected to the signal input line and detecting the presence or absence of connection in the multipolar plug by a voltage change in the signal input line;
An open switch provided between a connection point of the resistor on the voltage supply line side and the voltage adjusting resistor disposed on the voltage supply line;
An input switching device comprising: control means for controlling the open switch so that the open switch is closed after the detection means detects the connection of the multipolar plug. The resistance value of the resistor is
More than a value obtained as a result of multiplying the resistance value in the input device by the level ratio between the high level and the low level set as the voltage change detection threshold for the detection means, the resistance value in the detection means, and the above The input switching device according to claim 1, wherein the input switching device is selected within a range equal to or less than a value obtained as a result of dividing the level ratio. The signal input line is
The input switching device according to claim 1, wherein the input switching device is an audio input line connected to a connector terminal corresponding to one plug terminal to which a microphone is connected. The control means includes
After the connection of the audio input source is detected by the detection unit, the display unit is controlled to display an icon indicating that a noise canceling earphone or headphone is connected. The input switching device according to claim 3. The control means includes
After the connection of the multipolar plug is detected by the detection means, the filter processing means is controlled to set a filter coefficient having a frequency characteristic corresponding to noise canceling to the filter processing means. The input switching device according to claim 3, wherein First detecting a voltage change in a signal input line connected to a connector terminal corresponding to one plug terminal to which a predetermined input device is connected among a plurality of connector terminals arranged in a connector corresponding to the multipolar plug. And the steps
After the connection in the multipolar plug is detected by the voltage change, the voltage adjusting resistor disposed on the voltage supply line for supplying a voltage to the input device via the signal input line, and the voltage supply And a second step of controlling the open switch provided between the line and the connection point on the voltage supply line side in the resistor between the signal input lines to be closed. . Against the computer,
Among the plurality of connector terminals arranged in the connector corresponding to the multipolar plug, the multipolar plug is caused by a voltage change in a signal input line connected to a connector terminal corresponding to one plug terminal to which a predetermined input device is connected. Waiting for notification that the connection in the multipolar plug has been detected from the detection means for detecting the presence or absence of the connection in
After receiving the notification, the voltage adjustment resistor disposed on the voltage supply line for supplying a voltage to the input device via the signal input line, and between the voltage supply line and the signal input line A program that causes an open switch provided between a resistor and a connection point on the voltage supply line side to be closed.

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