JP2005267812A - Optical disk player - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical disk player capable of executing special play back by the same operation as that when the special play back of an analog record is executed in the case of executing special play back of an optical disk such as a CD. <P>SOLUTION: This player includes an operation disk part for instructing the reading speed and order of audio data; a control part for controlling the reading of the audio data according to the instruction of the operation disk part; an elastic part disposed in the bottom surface of the operation disk part; a support part for supporting the operation disk part and the elastic part; a rotation detection part for detecting the rotational speed and direction of the operation disk part to generate a rotation detecting signal; and a pressure detection part for detecting the pressing of the operation disk part to generate a pressing detection signal. The control part controls the reading speed and order of the audio data on the basis of a rotation detecting signal when the rotation detecting signal and a pressing detection signal are input, and controls only the reading speed of the audio data on the basis of the rotation detecting signal when the rotation detecting signal alone is input. <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 DJ (Disc Jockey) that plays audio data by operating an audio playback device may perform special playback called scratch playback that generates sound effects such as a rubbing sound while playing back audio data. . When the DJ performs scratch reproduction using an analog record player, the DJ generates a rubbing sound by quickly rotating the analog record in the clockwise direction or the counterclockwise direction. In addition, there is an optical disk reproducing apparatus capable of performing scratch reproduction similar to scratch reproduction performed using this analog record player.

  This optical disk playback device includes a jog dial and a memory, stores audio data read from an optical disk such as a CD (Compact Disc) in the memory, and stores the data in the memory by rotating the jog dial clockwise or counterclockwise. By controlling the reading speed and reading order of the recorded audio data, it is possible to generate a sound effect equivalent to a rubbing sound by an analog record. In this way, when playing audio data recorded on a CD, a DJ can perform scratch playback similar to an analog record by rotating the jog dial in the same way as an analog record (for example, (See Patent Document 1).

  An optical disk reproducing device as disclosed 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 not operated. When the jog dial is rotated, the optical disk playback device detects the rotation speed and rotation direction of the jog dial, and according to the detected rotation speed and rotation direction, the audio data read speed and read data read from the CD and stored in the memory. Control the order.

Japanese Patent Laid-Open No. 11-86446

  In an optical disk reproducing apparatus as disclosed in Patent Document 1, when the DJ rotates the jog dial and releases the 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. When the playback speeds match, the audio data being played back from another analog record player is switched to the audio data that matches the playback speed, so that the two audio data can be switched without a sense of incongruity. An optical disk reproducing device as disclosed 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 accustomed to the operation of the analog record player are not satisfied with the operation of the optical disc playback apparatus 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. A disc-shaped operation disk unit for instructing the reading speed and reading order of the audio data stored in the control unit, and a control unit for controlling reading of the audio data stored in the storage unit in response to an instruction from the operation disk unit. In the optical disk reproducing apparatus provided, a disk-like elastic part provided below the operation disk part, a support part that supports the operation disk part and an inner peripheral part of the elastic part, and a rotational speed of the operation disk part A rotation detection unit that detects a rotation direction and generates a rotation detection signal; and an outer peripheral part of the operation disk part that is positioned below the elastic part is pressed to deform the elastic part. A pressing detection unit that detects that the outer peripheral portion of the operation disk unit is pressed by contacting the elastic unit and generates a pressing detection signal, and the control unit receives the rotation detection signal and the pressing detection signal. When input, it controls the reading speed and reading order of audio data stored in the storage unit based on the rotation detection signal, and when only the rotation detection signal is input, the storage unit based on the rotation detection signal Only the reading speed of the audio data stored in is controlled.

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

  According to a third aspect of the present invention, in the optical disk reproducing apparatus according to the first or second aspect, a mat portion having substantially the same shape as the operation disk portion is provided between the operation disk portion and the elastic portion. It is characterized by providing.

  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. One embodiment of the present invention is a CD player that includes a jog dial in an operation unit and can change the reading speed and reading order of digital audio data reproduced from a CD and stored in a RAM according to the rotating speed and rotating direction of the jog dial. It is.

  FIG. 1 is a block diagram showing a configuration of a CD player 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.

  The turntable 1 fixed to the spindle motor 2 fixes the CD. When there is an instruction to start reproduction from the operation unit 12, the servo control unit 3 controls to rotate the spindle motor 2 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 12 includes a playback button, a playback stop button, an eject button, and a jog dial.

  FIG. 2 is a diagram showing a side cross section of the jog dial provided in the operation unit 12 of the CD player according to the embodiment of the present invention. In FIG. 2, 21 is a CD player casing, 21a is a support, 21b is a hole provided in the support, 22 is a bearing, 23 is a rotating shaft, 24 is an E-ring, 25 isher, and 26 is an elastic part. 26a is a cutting part, 27 is a mat part, 28 is an operation disk part, 29 is a guide part, 30 is a holding part, 31 is a screw, 32 is a scale holding part, 33 is a screw, 34 is a scale part, and 35 is a screw. , 36 is a rotation detector, 37 is a pressure detector, 38 is a substrate, 39 is a screw, and 40 is a stopper. In the CD player of this embodiment, the operation disk portion 28 is about 12 cm in diameter.

  In FIG. 2, the housing portion 21 is provided with a support portion 21 a that supports the operation disk portion 28, the mat portion 27, and the elastic portion 26. The support portion 21a has a circular shape with a diameter of 4 to 6 cm around the rotation shaft 23, and is provided with a plurality of holes 21b. The bearing 22 is fixed to the housing portion 21 by an E ring 24. The rotating shaft 23 is inserted into the bearing 22 via a washer 25. The support portion 21a supports the elastic portion 26 by inserting a cut and raised portion 26a provided in the elastic portion 26 into the hole 21b. The elastic part 26 is a disk-shaped leaf spring having a substantially the same radius as the operation disk part 28 and made of a metal. The elastic portion 26 has an inner peripheral portion fixed to the support portion 21a by an adhesive member such as a double-sided tape.

  The mat portion 27 is a disc having a shape having substantially the same radius as the operation disc portion 28. The mat portion 27 is placed on the upper surface of the elastic portion 26 with the rotating shaft 23 inserted in the center thereof. The operation disk portion 28 is a disk made of vinyl chloride or the like and having a diameter of about 12 cm. The operation disk portion 28 is placed on the upper surface of the mat portion 27 with the rotation shaft 23 inserted in the center thereof. Accordingly, the support portion 21 a supports the inner peripheral portion of the elastic portion 26, the mat portion 27, and the operation disk portion 28. The mat portion 27 is used for the operation disk portion 28 to smoothly rotate on the elastic portion 26. The mat portion 27 is made of a resin material that has a small friction coefficient and is less likely to generate static electricity. The elastic part 26, the mat part 27, and the operation disk part 28 correspond to the turntable, slip mat, and analog record in the analog record player used by the DJ. Therefore, the DJ can operate the CD player of this embodiment with the same operation feeling as that of the analog record player.

  The guide part 29 determines the attachment position of the mat part 27. The holding part 30 is press-fitted into the rotary shaft 23 from the upper surface of the operation disk part 28. Further, the holding part 30 is fixed to the guide part 29 by a screw 31. Since the operation disk part 28 is sandwiched between the guide part 29 and the holding part 30, when the DJ rotates the operation disk part 28, the operation disk part 28, the holding part 30 and the rotating shaft 23 rotate integrally. . In addition, the holder 30 is provided with a mark indicating the rotation position so that the DJ can visually recognize the rotation state of the operation disk portion 28.

  The scale holding part 32 is fixed to one end of the rotating shaft 23 with a screw 33. The scale part 34 is fixed to the scale holding part 32 with screws 35. For this reason, the operation disk part 28 and the scale part 34 can rotate integrally through the rotating shaft 23. On the outer peripheral portion of the scale portion 34, rectangular slit portions are provided at equal intervals. When the material of the scale part 34 is a metal, the slit part is a rectangular opening. However, the shape of the opening is not limited to a rectangle, and may be an appropriate shape. In the case where a transparent or translucent plastic is used as the scale portion 34, the slit portion is formed by printing.

  The rotation detection unit 36 is an optical sensor for detecting the rotation state (rotation angle and rotation direction) of the scale unit 34 that rotates integrally with the operation disk unit 30. The rotation detection unit 36 includes an optical sensor a and an optical sensor b, and is fixed to the back surface of the housing unit 21 so that the slit portion of the scale unit 34 can be detected. When the rotation detection unit 36 detects the slit portion provided in the scale unit 34, the rotation detection unit 36 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 controls the control unit 11. Output to. In this embodiment, the pulse signal a and the pulse signal b having different phases are called rotation detection signals.

  The pressure detection unit 37 is provided on the upper surface of the housing unit 21 at equal intervals on the same circumference of a circle having a radius R around the rotation shaft 23. This radius R is substantially equal to the length from the rotating shaft 23 to the outer peripheral portion of the operation disk portion 28. The number of the press detection parts 37 is determined according to the size of the operation disk part 28 and the elastic strength of the elastic part 27. The pressure detection unit 37 is, for example, a soft touch type push switch, and preferably has a weak actuation force (1 N or less) and a movement amount (stroke) of 0.3 mm or less.

  When the DJ pushes the outer peripheral portion of the operation disk portion 28, the elastic portion 26, the mat portion 27, and the operation disk portion 28 are bent downward by a pressing force with the point D shown in FIG. 2 as a fulcrum. At this time, when the outer peripheral part of the elastic part 26 pushes down the switch part of the pressure detection part 37, the pressure detection part 37 generates a pressure detection signal and outputs it to the control part 11. As described above, the elastic portion 26 is a leaf spring, and when the outer peripheral portion of the operation disk portion 28 is pressed, the elastic portion 26 is elastically deformed and bent by the pressing force. When the DJ stops pressing the outer peripheral portion of the operation disk portion 28, the elastic portion 26 returns to the state before elastic deformation, so that the outer peripheral portion of the elastic portion 26 releases the pressing of the switch portion of the press detecting portion 37 and presses. The detection unit 37 stops outputting the press detection signal. In addition, a stopper 40 is provided on the upper surface of the casing unit 21 to limit the downward movement due to the bending of the operation disk unit 27 so that the switch unit of the press detection unit 37 does not move longer than a predetermined movement amount. It has been. For this reason, the stopper part 40 can prevent a load more than necessary from being applied to the switch part of the pressure detection part 37.

  The control unit 11 determines the rotation direction of the operation disk unit 28 based on the phase difference between the pulse signal a and the pulse signal b of the rotation detection signal input from the rotation detection unit 36. For example, when the phase difference between the pulse signal a and the pulse signal b is 90 °, when the operation disk portion 28 rotates in the clockwise direction, the pulse signal a has a phase difference of + 90 ° with respect to the pulse signal b. . Further, when the operation disk part 28 rotates 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 rotation speed of the operation disk unit 28 from the number of pulses of either the pulse signal a or the pulse signal b of the rotation detection signal input for a certain time.

  As will be described later, when both the rotation detection signal and the pressure detection signal are input, the control unit 11 reads the digital audio data 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 28. The memory control unit 7 is controlled to read out. 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 28 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 in ascending order at a reading speed corresponding to the rotation speed. . Further, when the operation disk portion 28 is rotated counterclockwise, the digital audio data stored in the RAM 8 is controlled to be read out in descending order at a reading speed corresponding to the rotation speed (scratch function). .

  In addition, when only the rotation detection signal is input from the state where neither the rotation detection signal nor the pressure detection signal is input, the control unit 11 reads the digital audio from the RAM 8 according to the determined rotation direction of the operation disk unit 28. The memory control unit 7 is controlled so as to increase or decrease the data reading speed. The memory control unit 7 controls the reading speed of the digital audio data stored in the RAM 8 (pitch bend function).

The playback operation of the CD player of this embodiment will be described. 3 and 4 are diagrams for explaining the reproduction operation of the digital audio data recorded on the CD of the CD player of this embodiment.
The DJ starts normal playback of the audio data recorded on the CD by pressing the playback button of the operation unit 12. The CD player of this embodiment performs normal playback when neither the rotation detection signal nor the press detection signal is input to the control unit 11, that is, when the operation disk unit 28 is not rotated.

  When performing scratch reproduction, the DJ quickly rotates clockwise or counterclockwise while pushing the outer peripheral portion of the operation disk portion 28 by hand during normal reproduction. Normally, when scratch reproduction 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. Also, when rotating an analog record, it is easier for the DJ to rotate the analog record by putting a hand on the outer periphery than the inner periphery of the analog record. Therefore, when the DJ operates the operation disk portion 28 with the same operation feeling as that of the analog record, the operation disk portion 28 is rotated while the outer peripheral portion is pressed downward.

  When the DJ rotates while pushing the outer peripheral portion of the operation disk portion 28, the elastic portion 26, the mat portion 27, and the operation disk portion 28 are elastically deformed by the pressing force with the point D shown in FIG. . At this time, when the outer peripheral part of the elastic part 26 pushes down the switch part of one or a plurality of press detection parts 37, the press detection part 37 generates a press detection signal and outputs it to the control part 11. Further, when the rotation detection unit 36 detects the slit portion provided in the rotating scale unit 34, the rotation detection unit 36 generates a rotation detection signal (the pulse signal a and the pulse signal b described above) and outputs the rotation detection signal to the control unit 11. Accordingly, when the DJ starts rotating operation (point A shown in FIG. 3) while pressing the outer peripheral portion of the operation disk portion 28, the rotation detection signal and the pressure detection signal are input to the control unit 11 as shown in FIG. The

  When both the rotation detection signal and the pressure detection signal are input, the control unit 11 digitally reads from the RAM 8 at the reading speed and reading order corresponding to the rotation speed and the rotation direction of the operation disk unit 28 determined based on the rotation detection signal. The memory control unit 7 is controlled to read the audio data.

  When the DJ is rotating while pressing the outer peripheral portion of the operation disk portion 28, the operation disk portion 28 abuts against the stopper portion 40 even if the force pushing the operation disk portion 28 becomes strong. It is possible to prevent an excessive load from being applied. Further, since the elastic portion 26 is fixed to the support portion 21a by an adhesive member, no rotational force is transmitted to the press detection portion 37 even if the operation disk portion 28 rotates. For this reason, the CD player of the present embodiment can prevent the press detection unit 37 from being damaged by the rotation operation of the operation disk unit 28. The elastic portion 26 can prevent the elastic portion 26 from rotating because the cut and raised portion 26a is inserted into the hole 21b provided in the support portion 21a even if the adhesive member is peeled off.

  When the DJ releases his / her hand from the operation disk part 28 and ends the scratch reproduction (point B shown in FIG. 3), the mat part 27 and the operation disk part 28 return to the state before the elastic part 26 is elastically deformed, and the operation disk part It returns to the state before 28 is pressed. When the elastic part 26 releases the pressing of the switch part of the pressing detection part 37, the pressing detection part 37 stops the output of the pressing detection signal to the control part 11. When the rotation detection signal is input from the rotation detection unit 36 and the input of the pressure detection signal from the pressure detection unit 37 is stopped, the control unit 11 causes the memory control unit 7 to read the digital audio from the RAM 8 at the read speed during normal reproduction. Control to read data. That is, as shown in FIG. 3, when both the rotation detection signal and the pressure detection signal are input, the control unit 11 controls to read out the digital audio data from the RAM 8 based on the rotation detection signal, and presses the pressure detection signal. Is stopped and only the rotation detection signal is input (part C in FIG. 3), the digital audio data is controlled to be read from the RAM 8 at the reading speed during normal reproduction. Therefore, even if the rotation detection signal (C portion shown in FIG. 3) generated while the operation disk portion 28 is rotated by inertia is input to the control unit 11, the CD player of this embodiment is When the input of the pressure detection signal 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 a pitch bend operation, the DJ manually rotates the inner peripheral portion of the operation disk portion 28 in the clockwise direction or the counterclockwise direction during normal reproduction. Since the support part 21a is provided below the inner peripheral part of the operation disk part 28, the elastic part 26 can be rotated even if the inner peripheral part of the operation disk part 28 is rotated clockwise or counterclockwise while being pushed. Therefore, the mat part 27 and the operation disk part 28 do not bend. For this reason, since the elastic part 26 releases the pressing of the switch part of the pressure detection part 37, the pressure detection part 37 does not output a pressure detection signal to the control part 11. On the other hand, the rotation detecting unit 36 detects the slit portion provided in the scale unit 34 because the operation disk unit 28 is rotated, and generates a rotation detection signal (pulse signal a and pulse signal b). 11 is output.

  When the control unit 11 enters a state in which only the rotation detection signal is input from a state in which neither the rotation detection signal nor the pressure detection signal is input, the control unit 11 is based on the phase difference between the pulse signal a and the pulse signal b of the rotation detection signal. 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 determined rotation direction of the operation disk unit 28. For example, when the DJ starts to rotate the inner circumference of the operation disk portion 28 in the clockwise direction (point E shown in FIG. 4), only the rotation detection signal is input to the control unit 11 as shown in FIG. . The control unit 11 increases the speed of the digital audio data read from the RAM 8 according to the number of rotations of the operation disk unit 28 (the number of pulses of the input pulse signal a or pulse signal b) from the input rotation detection signal. The memory control unit 7 is controlled so as to go. On the other hand, when the DJ rotates the operation disk unit 28 counterclockwise, the control unit 11 reads the speed of the digital audio data read from the RAM 8 according to the rotation number of the operation disk unit 28 from the input rotation detection signal. The memory control unit 7 is controlled so as to lower the value. When the DJ finishes the rotation operation of the rotation operation unit 28, the rotation detection unit 36 stops outputting the rotation detection signal to the control unit 11 (point F shown in FIG. 4). When the input of the rotation detection signal from the rotation detection unit 36 is stopped, the control unit 11 causes the memory control unit 7 to control to read the digital audio data from the RAM 8 at the read speed during normal reproduction.

FIG. 5 is a flowchart for explaining the reproducing operation of the CD player of this embodiment.
Step 1 shown in FIG. 5 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 rotation detection signal nor the pressure detection 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.

  Step 3 is a step in which the control unit 11 determines whether or not a rotation detection signal is input from the rotation detection unit 36 to the control unit 11. When the operation disk unit 28 is rotated, the rotation detection unit 36 detects a slit unit provided in the scale unit 34, generates a rotation detection signal (pulse signal a and pulse signal b), and inputs it to the control unit 11. To do. When the rotation detection 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 or not a press detection signal is input to the control unit 11. In step 3, when the DJ rotates while pressing the outer peripheral portion of the operation disk portion 28, the elastic portion 26 is elastically deformed and pushes down the switch portion of the pressure detection portion 37, so that the pressure detection portion 37 generates a pressure detection signal. To do. Further, since the operation disk unit 28 is rotated, the rotation detection unit 36 generates a rotation detection signal. Therefore, when the DJ starts the rotation operation (point A shown in FIG. 3) while pressing the outer peripheral portion of the operation disk part 28, the control unit 11 receives the rotation detection signal and the pressure detection signal as shown in FIG. Both are entered. When the rotation detection signal and the pressure detection signal are input to the control unit 11, the process proceeds to Step 5.

  In step 3, when the DJ rotates the inner peripheral portion of the operation disk portion 28, the pressing force is applied to the support portion 21a and the elastic portion 26 does not elastically deform, so that the mat portion 27 and the operation disk portion 28 bend. Absent. For this reason, since the elastic part 26 cancels | releases the press of the switch part of the press detection part 37, the press detection part 37 does not generate | occur | produce a press detection signal. Further, since the operation disk unit 28 is rotated, the rotation detection unit 36 generates a rotation detection signal. Therefore, when the DJ rotates the inner periphery of the operation disk portion 28, only the rotation detection signal is input to the control unit 11. If only the rotation detection 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 jog dial operation function to be a scratch function. As shown in FIG. 3, the control unit 11 controls the operation function of the jog dial to be a scratch function when the rotation detection signal and the press detection signal are input. Then, the control unit 11 reads the digital audio data read from the RAM 8 based on the rotation detection signal input from the rotation detection unit 36 when the operation disk unit 28 is rotated, and reads out the audio data in ascending order. (Or read in descending order).

  Step 6 is a step in which the control unit 11 determines whether or not the input of the press detection signal to the control unit 11 is stopped. When the DJ finishes the rotation operation of the operation disk part 28, the mat part 27 and the operation disk part 28 return to the state before the elastic part 26 is elastically deformed, and thus return to the state before the operation disk part 28 is pressed. . When the elastic part 26 does not depress the switch part of the pressure detection part 37, the pressure detection part 37 stops inputting the pressure detection signal to the control part 11. When the input of the press detection 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. When the input of the press detection 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 reading speed during normal reproduction. Here, after the rotation operation of the operation disk part 28 is completed, even if the operation disk part 28 rotates due to inertia and a rotation detection signal is input to the control part 11 as shown in part C of FIG. 11 controls to perform normal reproduction when the input of the press detection signal is stopped. For this reason, when the rotation operation of the operation disk portion 28 is finished, the normal reproduction can be returned from the scratch reproduction.

  Step 8 is a step in which the control unit 11 performs control to change the operation function of the jog dial to the pitch bend function. As shown in FIG. 4, when only the rotation detection signal is input, the control unit 11 controls the jog dial operation function to be a pitch bend function. The control unit 11 controls to increase or decrease the reading speed of the digital audio data read from the RAM 8 to the memory control unit 7 based on the rotation detection signal input from the rotation detection unit 36 when the operation disk unit 28 is rotated. To do.

  Step 9 is a step in which the control unit 11 determines whether or not the input of the rotation detection signal to the control unit 11 is stopped. When the rotation of the operation disk unit 28 stops, the rotation detection unit 36 stops inputting the rotation detection signal to the control unit 11. If input of the rotation detection signal is stopped, the process proceeds to step 7.

  As described above, in the CD player of the present embodiment, when the DJ performs a rotation operation while pushing the outer peripheral portion of the operation disk portion 28 by hand, the DJ player operates as a scratch function. In the CD player of this embodiment, the scratch reproduction is performed according to the rotation state of the operation disk portion 28, and when the DJ releases the operation disk portion 28 and the scratch reproduction is completed, the scratch reproduction is immediately returned to the normal reproduction. it can. Further, when the DJ rotates the inner peripheral portion of the operation disk portion 28 by hand, it operates as a pitch bend function. In the CD player of this embodiment, the DJ can selectively use the scratch reproduction operation and the pitch bend operation only by changing the position where the operation disk portion 28 is rotated.

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 of the Example of this invention. The figure explaining the reproduction | regeneration operation | movement of the digital audio data recorded on CD. The figure explaining the reproduction | regeneration operation | movement of the digital audio data recorded on CD. The flowchart explaining the reproduction | regeneration operation | movement of CD player of the Example of this invention.

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 unit, 12: operation unit, 13: display unit, 21: housing unit, 21a ... support unit, 21b ... hole, 22 ... bearing, 23 ... rotating shaft, 24 ... E ring, 25 ... washer, 26 ... elastic part, 26a ... cutting part, 27 ... mat part, 28 ... operation disk part, 29 ... guide part, 30 ... holding part, 31 ... screw, 32 ... scale holding part, 33 ... screw, 34 ... scale part, 35 ... Screw, 36 ... Rotation detection unit, 37 ... Press detection unit, 38 ... Substrate, 39 ... Screw, 40 ... Stopper unit

Claims (3)

A reading unit for reading audio data recorded on an optical disc, a storage unit for storing audio data read by the reading unit, and a disk-like operation for instructing the reading speed and reading order of audio data stored in the storage unit In an optical disk playback device comprising a disk part, and a control part that controls to read out audio data stored in the storage part according to an instruction from the operation disk part,
A disk-shaped elastic part provided below the operation disk part, a support part that supports the operation disk part and an inner peripheral part of the elastic part, and a rotation speed and a rotation direction of the operation disk part are detected and rotated. A rotation detection unit that generates a detection signal; and an outer peripheral part of the operation disk part that is positioned below the elastic part and is pressed against an outer peripheral part of the operation disk part to deform the elastic part, A pressure detection unit that detects that a pressure is detected and generates a pressure detection signal,
When the rotation detection signal and the pressure detection signal are input, the control unit controls the reading speed and reading order of the audio data stored in the storage unit based on the rotation detection signal, and only the rotation detection signal Is input, the optical disk reproducing apparatus controls only the reading speed of the audio data stored in the storage unit based on the rotation detection signal. The optical disk reproducing apparatus according to claim 1,
After the rotation detection signal and the pressure detection signal are input, the control unit stops the input of the pressure detection signal and inputs only the rotation detection signal, and the audio data stored in the storage unit is predetermined. An optical disc reproducing apparatus that controls reading at a reading speed and a reading order. In the optical disk reproducing apparatus according to claim 1 or 2,
An optical disk reproducing apparatus comprising a mat portion having substantially the same shape as the operation disk portion between the operation disk portion and the elastic portion.

Images