JP2005158099A - Optical disk reproduction device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical disk reproduction device which can reproduce an optical disk such as a CD and make the same special reproduction as when reproducing an analog record disk. <P>SOLUTION: This optical disk reproduction device has a read section to read the audio data recorded on an optical disk, a memory to store the audio data, a disk operating section to instruct the read speed and the sequential order of the audio data stored in the memory, a mechanism to move the disk operating section up and down, a 1st detector to detect the revolution speed and the direction of the disk operating section and to output a 1st control signal, a 2nd detector to detect that the disk operating section has moved to the lower position determined in advance and to output a 2nd control signal, and a control section to control the read speed and the read order of the audio signals following the 1st signal when the 1st and 2nd signals are inputted, but control only the read speed according to the 1st signal when only the 1st signal is inputted. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an optical disc reproducing apparatus including an operation disk unit that stores audio data read from an optical disc in a storage unit and instructs a reading speed and a reading order of the audio data stored in the storage unit.

A disc jockey (DJ, Disc Jockey) that operates an optical disc playback apparatus to play back audio data is playing back audio data recorded on an optical disc such as an analog record or a compact disc (CD). In some cases, special reproduction called scratch reproduction for generating sound effects such as rubbing sound is performed. When DJ performs scratch playback using an analog record player, the DJ is forced to manually rotate the analog record being played back in the clockwise direction, which is the normal rotation direction, or counterclockwise, which is the opposite direction. Generates a rubbing sound. Further, there is a DJ CD player capable of performing scratch reproduction similar to the scratch reproduction by the analog record player. This DJ CD player has an operation disk part (hereinafter referred to as a timely jog dial) and a storage part (memory), stores audio data reproduced from the CD in the memory, and rotates the jog dial clockwise or counterclockwise. By rotating, the reading speed and reading order of the audio data stored in the memory are controlled, and a sound effect equivalent to the rubbing sound by the analog record is generated. In this way, when a DJ is playing audio data recorded on a CD with a DJ CD player, the DJ can rotate the jog dial in the same way as an analog record to perform scratch playback similar to an analog record. (For example, refer to Patent Document 1).

  When a jog dial is not operated, a DJ CD player described in Patent Document 1 reproduces audio data recorded on a CD at a standard speed (hereinafter referred to as normal reproduction). When the jog dial is rotated, the CD player detects the rotation speed and rotation direction of the jog dial, and in accordance with the detected rotation speed and rotation direction, the audio data read speed and read order read from the CD and stored in the memory Scratch playback is performed.

Japanese Patent Laid-Open No. 11-86446

  In the DJ CD player described in Patent Document 1, when the DJ rotates the jog dial and releases his hand from the jog dial, the rotation of the jog dial may not stop immediately due to inertia. When performing scratch playback, the DJ rotates the jog dial quickly in the clockwise or counterclockwise direction, so when you release your hand from the jog dial to end scratch playback and return to normal playback, the jog dial rotates due to inertia. Since it takes time to stop, it is not possible to return from scratch playback to normal playback at the timing that the DJ intended. Therefore, in a CD player equipped with a jog dial, there is a problem that even if the jog dial is rotated like the analog record, it is impossible to generate a sound effect equivalent to the sound effect due to scratch reproduction of the analog record.

  In addition, when playing an analog record by an analog record player, the DJ may perform an operation called pitch bend that rotates the analog record faster than a predetermined number of rotations or rotates it slower. The DJ can change the playback speed of the audio data by operating the pitch bend to match the playback speed of the audio data being played back from another analog record player. The DJ CD player described in Patent Document 1 includes a selection button for selecting a jog dial operation function (scratch function, pitch bend function, etc.). The DJ switches the jog dial operation function from the scratch function to the pitch bend function by operating this selection button. However, DJs who are accustomed to operating with an analog record player may feel uncomfortable with the operation of the DJ CD player because the operation of selecting the operation function of the jog dial using this selection button is different from the operation of the analog record player. There was a problem.

  The present invention has been made to solve the above-described problems, and provides an optical disk playback apparatus capable of performing scratch playback and pitch bend playback of an optical disk by the same operation as that for scratch playback and pitch bend playback of analog records. The purpose is to provide.

  In order to solve the above problems, the invention according to claim 1 of the present application includes a reading unit that reads audio data recorded on an optical disc, a storage unit that stores audio data read by the reading unit, and the storage unit. In the optical disc playback apparatus provided with an operation disk unit for instructing the reading speed and reading order of the audio data stored in the disk, a mechanism unit for moving the operation disk unit up and down, and a rotation speed and a rotation direction of the operation disk unit are set. A first detection unit that detects and outputs a first control signal; and a second detection unit that detects that the operation disk unit has been lowered to a predetermined position by the mechanism unit and outputs a second control signal. And when the first control signal and the second control signal are input, the audio data stored in the storage unit is read based on the first control signal. A control unit that controls the speed and reading order, and controls only the reading speed of the audio data stored in the storage unit based on the first control signal when only the first control signal is input. It is characterized by providing.

  The invention according to claim 2 of the present application is the optical disc reproducing apparatus according to claim 1, wherein the control unit receives the second control signal after the input of the first control signal and the second control signal. When the input of the control signal is stopped and only the first control signal is input, the audio data stored in the storage unit is controlled to be read at a predetermined reading speed and reading order.

  The invention according to claim 3 of the present application is the optical disk reproducing apparatus according to claim 1 or 2, wherein the mechanism portion has an elastic portion, and the elastic portion is located below the operation disk portion, The operation disk part moves up and down by the elastic force of the elastic part.

  According to a fourth aspect of the present invention, in the optical disc reproducing apparatus according to the first or second aspect, the mechanism portion has a plurality of magnetic portions, and the operation disk portion is an attractive force of the magnetic portion. Or it moves up and down by repulsion.

  According to the optical disk reproducing apparatus of the present invention, when scratch reproduction is performed using the jog dial, normal reproduction can be resumed immediately after the completion of scratch reproduction. Further, according to the optical disk reproducing apparatus of the present invention, it is possible to provide an optical disk reproducing apparatus capable of performing a pitch bend operation using a jog dial without requiring a function switching selection button.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a configuration of an optical disk reproducing apparatus according to an embodiment of the present invention. In FIG. 1, 1 is a turntable, 2 is a spindle motor, 3 is a servo control unit, 4 is an optical pickup, 5 is a reproduction amplifier, 6 is a signal processing unit, 7 is a memory control unit, and 8 is a RAM (Random Access Memory). , 9 is a DAC (Digital to Analog Converter), 10 is an output terminal, 11 is a control unit, 12 is an operation unit, and 13 is a display unit. An optical disk reproducing apparatus according to an embodiment of the present invention includes an operation disk unit as a jog dial unit in the operation unit 12, and is reproduced from a CD and stored in a RAM 8 according to the rotation speed and rotation direction of the operation disk unit. This is a DJ CD player that can change the reading speed and reading order of audio data.

  The turntable 1 fixed to the spindle motor 2 fixes the CD. When an instruction to start reproduction is input from the operation unit 14, the servo control unit 3 performs control to drive the spindle motor 2 to rotate at a predetermined linear velocity. In addition, the servo control unit 3 controls a focus servo circuit and a tracking servo circuit (not shown) in order to correctly trace the laser beam from the optical pickup 4 in the CD pit row.

  Digital audio data read by the optical pickup 4 is shaped and amplified by a reproduction amplifier 5 and input to a signal processing unit 6. The signal processing unit 6 demodulates the digital audio data, extracts an error signal such as a focus error signal and a tracking error signal, and extracts a synchronization signal, and inputs the digital audio data to the memory control unit 7.

  The memory control unit 7 controls the input digital audio data to be input to the RAM 8. The RAM 8 stores the input digital audio data. The digital audio data stored in the RAM 8 is read out and input to the DAC 9 under the control of the memory control unit 7. The DAC 9 converts digital audio data into an analog audio signal. The analog audio signal converted by the DAC 9 is output from the output terminal 11.

  The display unit 13 displays the playback time, track number, etc. of the currently playing track. The operation unit 14 includes a jog dial unit, a playback button, a playback stop button, and an eject button.

  2 and 3 are views showing a side cross section of the jog dial portion of the CD player according to the first embodiment of the present invention. 2 and 3, 21 is an operation disk part, 22 is a disk part, 22a is a slit part, 22b is a projection part, 23 is a rotating shaft, 24 is an elastic part, 25 is a holding part, and 26 is a first optical sensor part. , 27 is a second optical sensor unit, 28 is a panel to which the operation disk unit 22 is attached, and 29 is a casing of the CD player. In the CD player of this embodiment, the operation disk portion 21 has a diameter of 10 cm to 30 cm (corresponding to the size of an analog record) and is attached to the upper surface of the CD player.

  The operation disk portion 21 has a rotation shaft 23 inserted in the center thereof and is fixed to the rotation shaft 23 with a screw (not shown). Similarly, the disk portion 22 has a rotating shaft 23 inserted into the center of the disk portion 22 and is fixed to the rotating shaft 23 with a screw (not shown). Therefore, since the operation disk part 21 and the disk part 22 have an integral structure via the rotation shaft 23, when the operation disk part 21 is rotated, the disk part 22 also rotates in the same manner as the operation disk part 21. Rotate at the same speed and direction of rotation. The rotating shaft 23 is held by a holding portion 25 attached to the panel 28 and is fixed to the housing portion 29 via an elastic portion 24 such as a spring or rubber.

  The disk portion 22 is provided with an annular slit portion 22a on the outer peripheral portion, and an annular protrusion 22b on the inner peripheral portion. The slit portion 22a is formed, for example, by printing with a rectangular paint or printing paint containing carbon.

  The first optical sensor unit 26 includes two optical sensors for detecting the rotational speed and the rotational direction of the disk unit 22 that rotates together with the operation disk unit 21, and the first optical sensor unit 26 is provided at the position where the slit unit 22a is detected. It is fixed. When the first optical sensor unit 26 detects the slit unit 22a, the first optical sensor unit 26 generates a pulse signal a and a pulse signal b having different phases (for example, a phase difference of 90 °) from the two optical sensors, and outputs them to the control unit 11. In this embodiment, the pulse signal a and the pulse signal b having different phases are referred to as a first control signal.

  As shown in FIG. 3, the second optical sensor unit 27 is configured such that the operation disk part 21 is pressed by an operator (DJ), the disk part 22 compresses the elastic part 24, and the disk part 22 is lowered to a predetermined position. The housing portion 29 is attached to a position where the protruding portion 22b is detected. The second optical sensor unit 27 inputs a second control signal to the control unit 11 when detecting the protrusion 22b.

  The control part 11 discriminate | determines the rotation direction of the operation disk part 21 based on the phase difference of the pulse signal a and the pulse signal b of the input 1st control signal. For example, when the phase difference between the pulse signal a and the pulse signal b is 90 °, the pulse signal a is about + 90 ° with respect to the pulse signal b when the operation disk portion 21 is rotated in the clockwise direction. It becomes a phase difference. Further, when the operation disk portion 21 is rotated counterclockwise, the pulse signal a has a phase difference of −90 ° with respect to the pulse signal b. Further, the control unit 11 determines the rotational speed of the operation disk unit 21 from the number of pulses of either the pulse signal a or the pulse signal b of the first control signal input for a certain time.

  As will be described later, when both the first control signal and the second control signal are input, the control unit 11 digitally reads from the RAM 8 at the read speed and read order corresponding to the determined rotation speed and rotation direction of the operation disk unit 21. The memory control unit 7 is controlled to read the audio data. The memory control unit 7 controls the reading speed and reading order of the digital audio data stored in the RAM 8 (reading audio data in ascending address or reading in descending order). For example, when the operation disk unit 21 is rotated in the clockwise direction, the control unit 11 performs control so that the digital audio data stored in the RAM 8 is read out in ascending order, and the operation disk unit 21 rotates in the counterclockwise direction. When the rotation operation is performed, the digital audio data stored in the RAM 8 is controlled to be read out in descending order.

  Further, as will be described later, when only the first control signal is input from the state where neither the first control signal nor the second control signal is input, the control unit 11 determines in the determined rotation direction of the operation disk unit 21. Accordingly, the memory control unit 7 is controlled so as to increase or decrease the reading speed of the digital audio data read from the RAM 8. The memory control unit 7 controls the reading speed of the digital audio data stored in the RAM 8.

The playback operation of the CD player of this embodiment using the operation disk portion 21 of the first embodiment will be described. FIG. 4 is a diagram for explaining the reproduction operation for the control signal.
The DJ starts normal playback of the audio data recorded on the CD by pressing the playback button of the operation unit 14. The CD player according to this embodiment performs normal reproduction when neither the first control signal nor the second control signal is input to the control unit 11, that is, when the operation disk unit 21 is not rotated.

  When performing scratch reproduction, the DJ quickly rotates clockwise or counterclockwise while pushing the operation disk portion 21 by hand during normal reproduction. Normally, when scratch playback is performed using an analog record player, the DJ performs a rotation operation while pressing the analog record in order to quickly rotate the analog record against the rotation of the turntable. When the part 21 is operated, the operation disk part 21 is rotated while being pressed downward. When the DJ rotates while pressing the operation disk part 21, as shown in FIG. 3, the elastic part 24 is compressed and the operation disk part 21 is lowered with respect to the panel 28 in the direction of the housing part 29. Since the operation disk part 21 and the disk part 22 have an integral structure, when the operation disk part 21 is lowered in the direction of the housing part 29, the disk part 22 is similarly lowered in the direction of the housing part 29. When the disk part 22 is lowered to a predetermined position, the second optical sensor part 27 detects the protrusion part 22b, generates a second control signal, and outputs it to the control part 11. Further, when detecting the slit portion 22a, the first optical sensor unit 26 generates a first control signal (the pulse signal a and the pulse signal b described above) and outputs the first control signal to the control unit 11. Therefore, when the rotation operation is started while the operation disk part 21 is pressed (point A shown in FIG. 4), the first control signal and the second control signal are generated and input to the control part 11 as shown in FIG. .

  When both the first control signal and the second control signal are input, the control unit 11 has a reading speed and a reading order corresponding to the rotation speed and the rotation direction of the operation disk unit 21 determined based on the first control signal. The memory control unit 7 is controlled to read digital audio data from the RAM 8.

  When the DJ releases his / her hand from the operation disk part 21 and ends the scratch reproduction (point B shown in FIG. 4), the operation disk part 21 moves upward by the elastic force of the elastic part 24 and presses as shown in FIG. Return to the previous position. At the same time, the disk part 22 also moves upward, and the second photosensor part 27 does not detect the protruding part 22b. Even when the first control signal is input from the first optical sensor unit 26, the control unit 11 reads the normal control signal to the memory control unit 7 when the input of the second control signal from the second optical sensor unit 27 is stopped. Control to read digital audio data from the RAM 8 at a speed. That is, as shown in FIG. 4, when both the first control signal and the second control signal are input, the control unit 22 controls to read digital audio data from the RAM 8 based on the first control signal, When the input of the second control signal is stopped and only the first control signal is input (part C shown in FIG. 4), the digital audio data is controlled to be read from the RAM 8 at the reading speed during normal reproduction. Therefore, even if the first control signal (C portion shown in FIG. 4) generated while the operation disk portion 21 is rotated by inertia is input to the control portion 11, the CD player of this embodiment controls When the input of the second control signal to the unit 11 is stopped, the normal reproduction can be returned from the scratch reproduction.

  Next, a case where a pitch bend operation is performed will be described. When performing pitch bend operation, the DJ rotates the operation disk part 21 clockwise during normal reproduction (by adjusting the force that the disk part 22 does not move down to the position where the second optical sensor part 27 detects the protrusion 22b). Rotate in direction or counterclockwise. When detecting the slit portion 22a, the first optical sensor unit 26 generates a first control signal (pulse signal a and pulse signal b) and outputs the first control signal to the control unit 11. At this time, since the disk part 22 does not go down to a predetermined position, the second optical sensor part 27 does not detect the protruding part 22b and does not output the second control signal.

  When the control unit 11 enters a state in which only the first control signal is input from a state in which neither the first control signal nor the second control signal is input, the level of the pulse signal a and the pulse signal b of the first control signal is increased. The memory control unit 7 is controlled to increase or decrease the reading speed of the digital audio data read from the RAM 8 according to the rotation direction of the operation disk unit 21 determined based on the phase difference. For example, when the DJ rotates the operation disk unit 21 in the clockwise direction, the control unit 11 reads from the RAM 8 according to the number of rotations of the operation disk unit 21 (the number of pulses of the input pulse signal a or pulse signal b). The memory control unit 7 is controlled so as to increase the speed of the read digital audio data. Conversely, when the DJ rotates the operation disk unit 21 in the counterclockwise direction, the control unit 11 decreases the speed of the digital audio data read from the RAM 8 in accordance with the number of rotations of the operation disk unit 21. The memory control unit 7 is controlled.

5 and 6 are views showing a side cross section of a jog dial portion of a CD player according to the second embodiment of the present invention. 5 and FIG. 6, the same parts as those in FIG. 5 and 6, 30 indicates a first magnet, and 31 indicates a second magnet.

  As shown in FIG. 5, the first magnet 30 is attached to the lower surface of the panel 28. The second magnet 31 is attached to the upper surface of the disk portion 22 so as to face the first magnet 30. The first magnet 30 and the second magnet 31 are attached so that different magnetic poles face each other. For this reason, the disk part 22 moves upward (in the direction of the panel 28) by the attractive force of the first magnet 30 and the second magnet 31 in a state where the operation disk part 21 is not pressed, and the operation disk part 21 also Move upward. As shown in FIG. 5, when the operation disk part 21 and the disk part 22 are moving upward, the protrusion 22 b provided on the disk part 22 is in a position where it is not detected by the second photosensor part 27.

  The playback operation of the CD player of this embodiment using the operation disk portion 21 of the second embodiment will be described. The DJ starts normal playback of the audio data recorded on the CD by pressing the playback button of the operation unit 14. The CD player according to this embodiment performs normal reproduction when neither the first control signal nor the second control signal is input to the control unit 11, that is, when the operation disk unit 21 is not rotated.

  When performing scratch reproduction, the DJ quickly rotates clockwise or counterclockwise while pushing the operation disk portion 21 by hand during normal reproduction. When the DJ rotates while pressing the operation disk portion 21, the operation disk portion 21 moves against the panel 28 against the panel 28, against the attractive force of the first magnet 30 and the second magnet 31. Go down in the direction. Since the operation disk part 21 and the disk part 22 have an integral structure, the disk part 22 is similarly lowered in the direction of the housing part 29. As shown in FIG. 6, when the disk part 22 is lowered to a predetermined position, the second optical sensor part 27 detects the protrusion part 22 b, generates a second control signal, and outputs it to the control part 11. Further, when detecting the slit portion 22 a, the first optical sensor unit 26 generates a first control signal (pulse signal a and pulse signal b) and outputs the first control signal to the control unit 11.

  When both the first control signal and the second control signal are input, the control unit 11 has a reading speed and a reading order corresponding to the rotation speed and the rotation direction of the operation disk unit 21 determined based on the first control signal. The memory control unit 7 is controlled to read digital audio data from the RAM 8.

  When the DJ releases his / her hand from the operation disk part 21 and the scratch reproduction is finished, the operation disk part 21 returns to the position before being pressed by the attractive force of the first magnet 30 and the second magnet 31 as shown in FIG. At the same time, the disk part 22 also moves upward, and the second photosensor part 27 does not detect the protruding part 22b. Even when the first control signal is input from the first optical sensor unit 26, the control unit 11 reads the normal control signal to the memory control unit 7 when the input of the second control signal from the second optical sensor unit 27 is stopped. Control to read digital audio data from the RAM 8 at a speed. That is, as shown in FIG. 4, when both the first control signal and the second control signal are input, the control unit 22 reads the digital audio data from the RAM 8 based on the first control signal, and performs the second control. When the input of the signal is stopped and only the first control signal is input, the digital audio data is controlled to be read from the RAM 8 at the reading speed during normal reproduction. Therefore, even if the first control signal (C portion in FIG. 4) generated while the operation disk unit 21 is rotated by inertia is input to the control unit 11, the CD player of the present embodiment When the input of the second control signal is stopped at 11, the normal playback can be resumed.

  Next, a case where a pitch bend operation is performed will be described. When performing pitch bend operation, the DJ rotates the operation disk portion 21 in the clockwise direction during normal reproduction (with a force that does not lower the disk portion 22 until the second optical sensor portion 27 detects the protrusion 22b). Or it is rotated counterclockwise. When detecting the slit portion 22a, the first optical sensor unit 26 generates a first control signal (pulse signal a and pulse signal b) and outputs the first control signal to the control unit 11. At this time, since the disk part 22 does not go down to a predetermined position, the second optical sensor part 27 does not detect the protruding part 22b and does not output the second control signal.

  When the control unit 11 enters a state in which only the first control signal is input from a state in which neither the first control signal nor the second control signal is input, the level of the pulse signal a and the pulse signal b of the first control signal is increased. The memory control unit 7 is controlled to increase or decrease the reading speed of the digital audio data read from the RAM 8 according to the rotation direction of the operation disk unit 21 determined based on the phase difference. For example, when the DJ rotates the operation disk unit 21 in the clockwise direction, the control unit 11 reads from the RAM 8 according to the number of rotations of the operation disk unit 21 (the number of pulses of the input pulse signal a or pulse signal b). The memory control unit 7 is controlled so as to increase the speed of the read digital audio data. Conversely, when the DJ rotates the operation disk unit 21 in the counterclockwise direction, the control unit 11 decreases the speed of the digital audio data read from the RAM 8 in accordance with the number of rotations of the operation disk unit 21. The memory control unit 7 is controlled.

  7 and 8 are views showing a side cross section of a jog dial portion of a CD player according to a third embodiment of the present invention. 7 and 8, the same parts as those in FIG.

  The detection switch 32 shown in FIG. 8 is fixed to the housing part 29 so as to contact the disk part 22. When the operation disk part 21 is lowered to a predetermined position and the disk part 22 presses the switch part of the detection switch 32, the detection switch 32 is supplied with a third control signal (the second light sensor part 27 described above generates the second control signal). This corresponds to the control signal). The first magnet 30 is attached to the lower surface of the disk portion 22. The second magnet 31 is attached to the housing portion 29 so as to face the first magnet 30. The first magnet 30 and the second magnet 31 are attached so that the same magnetic poles face each other. For this reason, the disk part 22 moves upward (in the direction of the panel 28) by the repulsive force of the first magnet 30 and the second magnet 31 when the operation disk part 21 is not pressed, and the operation disk part 21 also Move upward. As shown in FIG. 7, when the operation disk part 21 and the disk part 22 are moving upward, the disk part 22 is in a position where the switch part of the detection switch 32 is not pressed.

  The playback operation of the CD player of this embodiment using the operation disk portion 21 of the third embodiment will be described. The DJ starts normal playback of the audio data recorded on the CD by pressing the playback button of the operation unit 14. The CD player according to the present embodiment performs normal reproduction when neither the first control signal nor the third control signal is input to the control unit 11, that is, when the operation disk unit 21 is not rotated.

  When performing scratch reproduction, the DJ quickly rotates clockwise or counterclockwise while pushing the operation disk portion 21 by hand during normal reproduction. When the DJ rotates while pressing the operation disk portion 21, the operation disk portion 21 moves against the panel 28 against the repulsive force of the first magnet 30 and the second magnet 31, as shown in FIG. 8. Go down in the direction. Since the operation disk part 21 and the disk part 22 have an integral structure, the disk part 22 is similarly lowered in the direction of the housing part 29. When the disk part 22 is lowered to a predetermined position and presses the switch part of the detection switch 32, the detection switch 32 generates a third control signal and outputs it to the control part 11. Further, when detecting the slit portion 22 a, the first optical sensor unit 26 generates a first control signal (pulse signal a and pulse signal b) and outputs the first control signal to the control unit 11. Therefore, when the rotation operation is started while the operation disk portion 21 is pressed (point A shown in FIG. 4), the first control signal and the third control signal are generated and input to the control portion 11 as shown in FIG. .

  When both the first control signal and the third control signal are input, the control unit 11 has a reading speed and a reading order corresponding to the rotation speed and the rotation direction of the operation disk unit 21 determined based on the first control signal. The memory control unit 7 is controlled to read digital audio data from the RAM 8.

  When the DJ releases his / her hand from the operation disk part 21 and finishes the scratch reproduction, the operation disk part 21 returns to the position before being pressed by the repulsive force of the first magnet 30 and the second magnet 31 as shown in FIG. At the same time, the disk part 22 also moves upward, and the disk part 22 does not press the switch part of the detection switch 32. Even if the first control signal is input from the first optical sensor unit 26, the control unit 11 causes the memory control unit 7 to read the RAM 8 at the read speed during normal reproduction when the input of the third control signal from the detection switch 32 is stopped. Control to read digital audio data from That is, as shown in FIG. 4, when both the first control signal and the third control signal are input, the control unit 22 reads the digital audio data from the RAM 8 based on the first control signal, and performs the third control. When the input of the signal is stopped and only the first control signal is input, the digital audio data is controlled to be read from the RAM 8 at the reading speed during normal reproduction. Therefore, even if the first control signal (C portion in FIG. 4) generated while the operation disk unit 21 is rotated by inertia is input to the control unit 11, the CD player of the present embodiment When the input of the third control signal is stopped at 11, the normal playback can be resumed.

  Next, a case where a pitch bend operation is performed will be described. When performing pitch bend operation, the DJ performs normal playback (by adjusting the force so that the disk portion 22 does not move down to the position where the switch portion of the detection switch 32 is pressed), and the DJ rotates the operation disk portion 21 clockwise or counterclockwise. Rotate in the direction. When detecting the slit portion 22a, the first optical sensor unit 26 generates a first control signal (pulse signal a and pulse signal b) and outputs the first control signal to the control unit 11. At this time, the detection switch 32 does not output the third control signal because the disk portion 22 does not press the switch portion of the detection switch 32.

  When the control unit 11 enters a state in which only the first control signal is input from a state in which neither the first control signal nor the third control signal is input, the order of the pulse signal a and the pulse signal b of the first control signal is increased. The memory control unit 7 is controlled to increase or decrease the reading speed of the digital audio data read from the RAM 8 according to the rotation direction of the operation disk unit 21 determined based on the phase difference. For example, when the DJ rotates the operation disk unit 21 in the clockwise direction, the control unit 11 reads from the RAM 8 according to the number of rotations of the operation disk unit 21 (the number of pulses of the input pulse signal a or pulse signal b). The memory control unit 7 is controlled so as to increase the speed of the read digital audio data. Conversely, when the DJ rotates the operation disk unit 21 in the counterclockwise direction, the control unit 11 decreases the speed of the digital audio data read from the RAM 8 in accordance with the number of rotations of the operation disk unit 21. The memory control unit 7 is controlled.

FIG. 9 is a flowchart for explaining the reproducing operation of the CD player according to the first to third embodiments of the present invention.
Step 1 shown in FIG. 9 is a step of reading the digital audio data recorded on the CD and storing the read digital audio data in the RAM 8.
Step 2 is a step in which the control unit 11 performs control to read digital audio data from the RAM 8 at a reading speed during normal reproduction. When neither the first control signal nor the second control signal (or the third control signal) is input, the control unit 11 controls the memory control unit 7 to read the digital audio data from the RAM 8 at the read speed during normal reproduction. To do.

  Step 3 is a step in which the control unit 11 determines whether or not the first control signal is input from the first optical sensor unit 26 to the control unit 11. When the operation disk part 21 is rotated, the first sensor part 26 detects the slit part 22a, generates a first control signal (pulse signal a and pulse signal b), and outputs it to the control part 11. When the first control signal is input to the control unit 11, the process proceeds to step 4.

  Step 4 is a step in which the control unit 11 determines whether the second control signal is input to the control unit 11 or whether the third control signal is input to the control unit 11. In step 3, when the operation disk portion 21 is rotated while being pressed downward, and the second sensor portion 27 detects the protrusion 22b and generates a second control signal, both the first control signal and the second control signal are generated. Input to the control unit 11. Alternatively, when the disk portion 22 presses the switch portion of the detection switch 32 and the detection switch 32 generates the third control signal, both the first control signal and the third control signal are input to the control portion 11. Accordingly, when the rotation operation is started while the operation disk portion 21 is pressed (point A shown in FIG. 4), the first control signal and the second control signal or the third control signal are sent to the control unit 11 as shown in FIG. Entered. When the first control signal and the second control signal or the third control signal are input to the control unit 11, the process proceeds to step 5. When only the first control signal is input to the control unit 11, the process proceeds to Step 8.

  Step 5 is a step in which the control unit 11 controls the operation function of the operation disk unit 21 to be a scratch function. As shown in FIG. 4, when the first control signal and the second control signal or the third control signal are input, the control unit 11 controls the operation function of the operation disk unit 21 to be a scratch function. Then, the control unit 11 reads the digital audio data read from the RAM 8 based on the first control signal input from the first optical sensor unit 26 and the reading order (reading the audio data in ascending address or reading in descending order). To control.

  Step 6 is a step in which the control unit 11 determines whether or not the input of the second control signal or the third control signal to the control unit 11 is stopped. When the rotation operation is completed and the operation disk portion 21 returns to the position before being pressed by the elastic force of the elastic portion 24 as shown in FIG. 2, the second sensor portion 27 outputs a second control signal to the control portion 11. To stop. Alternatively, the detection switch 32 stops the output of the third control signal to the control unit 11. When the input of the second control signal or the third control signal is stopped, the process proceeds to step 7.

  Step 7 is a step in which the control unit 11 controls to read out the digital audio data from the RAM 8 at the reading speed during normal reproduction. As shown in FIG. 4, when the input of the second control signal or the third control signal is stopped, the control unit 11 controls the memory control unit 7 to read the digital audio data from the RAM 8 at the read speed during normal reproduction. Here, after the rotation operation of the operation disk part 21 is completed, even if the operation disk part 21 rotates due to inertia and the first control signal is input to the control part 11 as shown in part C of FIG. The unit 11 performs control to perform normal reproduction when the input of the second control signal or the third control signal is stopped. For this reason, when the rotation operation of the operation disk portion 21 is finished, the normal reproduction can be returned from the scratch reproduction.

  Step 8 is a step in which the control unit 11 controls the operation function of the operation disk unit 21 to be a pitch bend function. When only the first control signal is input, the control unit 11 controls the operation function of the operation disk unit 21 to be a pitch bend function. Then, the control unit 11 controls the memory control unit 7 to increase or decrease the reading speed of the digital audio data read from the RAM 8 based on the first control signal input from the first optical sensor unit 26.

  Step 9 is a step in which the control unit 11 determines whether or not the input of the first control signal to the control unit 11 is stopped. When the rotation of the operation disk unit 21 stops, the first sensor unit 26 stops the input of the first control signal to the control unit 11. When the input of the first control signal is stopped, the process proceeds to step 7.

  In the second embodiment described above, one of the first magnet 30 and the second magnet 32 can be an iron plate or the like. Further, in the second and third embodiments, the first magnet 30 and the second magnet 32 can be electromagnets, and the attractive or repulsive force of the electromagnet is adjusted by adjusting the current flowing through the electromagnet. can do.

  As described above, in the CD player of this embodiment using the operation disk portion 21 of the embodiment, the DJ performs scratch reproduction while pushing the operation disk portion 21 by hand, and releases the hand from the operation disk portion 21 to perform scratch reproduction. Upon completion, the normal reproduction can be returned from the scratch reproduction. Further, the scratch reproduction or the pitch bend operation can be performed according to the force applied to the operation disk portion 21.

1 is a block diagram showing a configuration of a CD player that is an embodiment of the present invention. The figure which shows the side cross section of the jog dial part of 1st Example of this invention (state which the operation disc part is not pressed). The figure which shows the side cross section of the jog dial part of 1st Example of this invention (state in which the operation disc part was pressed). The figure explaining the reproduction | regeneration operation | movement with respect to a control signal. The figure which shows the side cross section of the jog dial part of the 2nd Example of this invention (state in which the operation disk part is not pressed). The figure which shows the side cross section of the jog dial part of the 2nd Example of this invention (state in which the operation disc part was pressed). The figure which shows the side cross section of the jog dial part of the 3rd Example of this invention (state which the operation disc part is not pressed). The figure which shows the side cross section of the jog dial part of the 3rd Example of this invention (state in which the operation disc part was pressed). 6 is a flowchart for explaining a reproducing operation of the CD player according to the embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Turntable, 2 ... Spindle motor, 3 ... Servo control part, 4 ... Optical pick-up, 5 ... Reproduction amplifier, 6 ... Signal processing part, 7 ... Memory control part, 8 ... RAM, 9 ... DAC, 10 ... Output terminal , 11 ... control part, 12 ... operation part, 13 ... display part, 21 ... operation disk part, 22 ... disk part, 22a ... slit part, 22b ... projection part, 23 ... rotating shaft, 24 ... elastic part, 25 ... holding , 26 ... first optical sensor unit, 27 ... second optical sensor unit, 28 ... panel, 29 ... housing unit, 30 ... first magnet, 31 ... second magnet, 32 ... detection switch

Claims (4)

A reading unit that reads audio data recorded on the optical disc, a storage unit that stores the audio data read by the reading unit, and an operation disk unit that instructs the reading speed and reading order of the audio data stored in the storage unit; In an optical disk playback device comprising:
A mechanism for moving the operation disk up and down;
A first detection unit that detects a rotation speed and a rotation direction of the operation disk unit and outputs a first control signal;
A second detection unit for detecting that the operation disk unit has been lowered to a predetermined position by the mechanism unit and outputting a second control signal;
When the first control signal and the second control signal are input, the audio data reading speed and reading order stored in the storage unit are controlled based on the first control signal, and the first control signal is read out. An optical disc reproducing apparatus comprising: a control unit that controls only a read speed of audio data stored in the storage unit based on the first control signal when only a control signal is input. The optical disk reproducing apparatus according to claim 1,
After the input of the first control signal and the second control signal, when the input of the second control signal is stopped and only the first control signal is input, the control unit is stored in the storage unit. An optical disc reproducing apparatus that controls to read out the audio data at a predetermined reading speed and reading order. In the optical disk reproducing apparatus according to claim 1 or 2,
The optical disk reproducing apparatus characterized in that the mechanism part has an elastic part, the elastic part is located below the operation disk part, and the operation disk part moves up and down by the elastic force of the elastic part. In the optical disk reproducing apparatus according to claim 1 or 2,
The mechanism part has a plurality of magnetic parts,
2. The optical disk reproducing apparatus according to claim 1, wherein the operation disk part moves up and down by attraction or repulsion of the magnetic part.

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