JP2009104696A - Optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical disk device for reducing distortion of a signal between both connectors by setting optimal bending angle of the bent part of an FFC for connecting the connector of a printed circuit board of an optical pickup unit to the connector of a main-printed circuit board. <P>SOLUTION: The FCC 3 includes: a movable line part 3a having a substantially S shape viewed from the side so that the printed circuit board 4 of an optical pickup unit is moved in a disk radial direction, and one end 31 is connected to the connector 6 of the printed circuit board 4 of the optical pickup unit; and a fixed line part 3b having one end connected to the other end of the movable line part 3a and the other end 32 connected to the connector of a main-printed circuit board 2. Bent parts R1 and R2 formed in the fixed line part 3b have bending angles of, e.g., 45°, so as to reduce the change of characteristic impedance of a transmission line, and wired to predetermined places in the device. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention has an arrangement in which a connector of a printed wiring board of an optical pickup unit and a connector of a main printed wiring board are connected by a flat flexible cable, and reproduces or records / reproduces information with respect to an optical disk. In particular, the present invention relates to a bending angle when wiring a flat flexible cable.

  FIG. 5 is a simplified board layout diagram for explaining a wiring state of an FFC (flat flexible cable) for connecting a printed wiring board of an optical pickup unit provided in a loader unit and a main printed wiring board in a conventional optical disk apparatus. It is. FIG. 6 illustrates the wiring state of the fixed line portion excluding the movable line portion of the FFC that connects the printed wiring board of the optical pickup unit provided in the loader portion and the main printed wiring board in the conventional optical disc apparatus. It is the simplified board | substrate layout figure. FIG. 7 is a simplified configuration diagram for explaining a state in which the printed wiring board of the optical pickup unit and the movable line portion of the FFC are viewed from the side.

  5 and 6, the connector 6 of the printed wiring board 4 of the optical pickup unit in the loader unit 1 in the optical disc apparatus B is connected to the connector 7 of the main printed wiring board 2 through the FFC 3 having a plurality of signal lines. Has been. 5, 6, and 7, the loader unit 1 is provided with a printed wiring board 4 of an optical pickup unit on which an optical pickup (not shown) is mounted. The printed wiring board 4 of the optical pickup unit is a thread (not shown). The mechanism is configured to move in the vertical direction (disk radial direction) as seen from the drawing along the guide rail 5. One end 31 of the FFC 3 is connected to the connector 6 of the printed wiring board 4 of the optical pickup unit. The other end 32 of the FFC 3 is connected to the connector 7 of the main printed wiring board 2.

  In FFC3 shown in FIGS. 5 and 7, a represents one point on the one end 31 side of the substantially S-shaped movable line portion 3a of FFC3, b represents one point of the bent portion of the movable line portion 3a of FFC3, and c represents FFC3. One point of the boundary between the movable line portion 3a and the fixed line portion 3b is shown.

In the fixed line portion 3b of the FFC 3 shown in FIG. 6, it is bent 90 degrees upward along the side between the point m1 and the point e1 as viewed from the figure, and along the side between the point i and the point j. Is bent 90 degrees downward as viewed from the side, and further bent 90 degrees rightward from the figure along the side between the points f1 and h1, and includes these bent portions L1, L2, and L3 to fix the FFC 3 The line portion 3 b is wired at a predetermined location in the optical disc apparatus B. In FIG. 6, the movable line portion of the FFC 3 is not shown in order to make the shape of the fixed line portion 3b of the FFC 3 easy to understand.
W02002 / 084665 gazette JP 2002-321424 A JP 2003-91943 A

  However, in this conventional optical disc apparatus B, the bending angle of the bent portions l1, l2, and l3 of the fixed line portion 3b of the FFC 3 is set to 90 degrees, and thus the following problems occur.

  FIG. 8 shows a part of the FFC including the bent portion of the fixed line portion in the FFC for explaining the signal flow when the bending angle of the bent portion of the fixed line portion in the FFC is set to 90 degrees in the conventional optical disc apparatus. FIG.

  As shown in FIG. 8, when the signal S1 flows through a certain signal line in the fixed line portion 3b of the FFC 3, it is reflected by the bent portion L, and as a result, the direction is changed by 90 degrees. The characteristic impedance of the transmission line changes greatly due to the change in the pattern of the transmission line in the bent portion L. In other words, when the bending angle of the bent portion L is 90 degrees, reflection occurs with respect to the signal S1 at the bent portion L and crosstalk occurs, thereby increasing the distortion of the waveform of the signal S1 and inputting the signal S1. There arises a problem that the control accuracy of the control circuit mounted on the main printed wiring board 2 is lowered and the stability of the control is lowered. The same problem occurs for other signals S2 and the like.

  FIG. 9 is a graph showing the relationship between the frequency of the signal input to the FFC having a 90-degree bent portion and the gain of the signal input to the FFC and output from the FFC. Here, it is assumed that one bent portion is provided in the FFC.

  In FIG. 9, the horizontal axis indicates the frequency of the signal input to the FFC having the 90-degree bent portion (the frequency of the signal output from the printed wiring board of the optical pickup unit), and the vertical axis indicates the input to the FFC. The gain level (dB) of the signal output from the FFC is shown. G1 represents an FFC having a 90 ° bent portion with respect to the frequency of the signal input to the FFC having a 90 ° bent portion (the frequency of the signal output from the printed wiring board of the optical pickup unit). 6 is a line showing a change in gain of a signal output from the FFC via the FFC.

  According to this line G1, in the range where the frequency of the signal output from the printed wiring board of the optical pickup unit is low (about 0 Hz to 10 MHz), the output signal is connected to the main print via the FFC having a 90 degree bent portion. It shows that the gain when reaching the wiring board hardly changes. That is, in the range where the frequency of the signal output from the printed circuit board of the optical pickup unit is low (0 Hz to 10 MHz), even if the folding angle of the FFC bent portion is 90 degrees, the signal is reflected by the bent portion. It can be inferred that there is almost no flow.

  However, in the range where the frequency of the signal output from the printed wiring board of the optical pickup unit is relatively high (from 20 MHz to 80 MHz), the signal is often reflected at the bent portion where the FFC bending angle is 90 degrees. It can be seen that the gain of the signal when it reaches the main printed circuit board changes greatly. That is, when there is a discontinuous point (a point that changes greatly) in the characteristic impedance, the signal gain is more easily affected by the high frequency. Therefore, it can be inferred that the signal is largely reflected at the bent portion and the waveform distortion is increased.

  Furthermore, in the range where the frequency of the signal output from the printed circuit board of the optical pickup unit is high (about 90 MHz or more), the signal is further reflected at the bent portion where the FFC bending angle is 90 degrees, and is high. It can be seen that the frequency is easily affected by noise, so that the gain of the signal when reaching the main printed wiring board is greatly changed and considerably decreased. That is, in the range where the frequency of the signal output from the printed circuit board of the optical pickup unit is high (about 90 MHz or more), the folding angle of the FFC bent portion is 90 degrees, so that the signal is further reflected at the bent portion. It can be estimated that a large amount of distortion occurs, and that the waveform is more susceptible to noise at a high frequency, and the waveform distortion is further increased.

  In short, in the conventional optical disc apparatus B, the bending angles of the bent portions L1, L2, and L3 of the FFC 3 that connect the connector 6 of the printed wiring board 4 of the optical pickup unit and the connector 7 of the main printed wiring board 2 are 90 degrees. Therefore, the signal output from the connector 6 of the printed wiring board 4 of the optical pickup unit reaches the connector 7 of the main printed wiring board 2 via the FFC 3 having the bent portions L1, L2, and L3 of 90 degrees. At this time, the signal waveform is distorted due to the above-described causes, so that there is a problem that the control accuracy of the control circuit mounted on the main printed wiring board 2 is lowered and the control stability is lowered.

  The prior art of Patent Document 1 has a configuration in which a tray side connection part of a disk drive device and a main body side connection part on the main body chassis side are electrically connected using a flat belt-like connection line. There is no disclosure about optimizing the bending angle of the bent portion of the flat flexible cable connecting the connector of the printed wiring board of the optical pickup unit and the connector of the main printed wiring board, and the printing of the optical pickup unit. There is no disclosure of a measure for reducing the distortion of the waveform of the signal between the connector on the wiring board and the connector on the main printed wiring board.

  The prior art of Patent Document 2 discloses a flexible wiring board that does not require a bent portion of the flexible wiring board to be stopped with a tape or the like, but this conventional technique is also a connector for a printed wiring board of an optical pickup unit. There is no disclosure about optimizing the bending angle of the bent portion of the flat flexible cable that connects the connector of the main printed wiring board to the main printed wiring board, and the connector of the printed wiring board of the optical pickup unit and the main printed wiring board No measures for reducing the distortion of the signal waveform between the connector and the connector are disclosed.

  The prior art of Patent Document 3 is configured to reduce the load associated with the increase in the wiring pattern. This prior art also includes a connector for the printed wiring board of the optical pickup unit and a connector for the main printed wiring board. There is no disclosure about optimizing the bending angle of the bent portion of the flat flexible cable to be connected, and the waveform of the signal between the connector of the printed circuit board of the optical pickup unit and the connector of the main printed circuit board is not disclosed. No measures for reducing distortion are disclosed.

  The present invention has been made to solve the above-described problems. The bending angle of the bent portion of the flat flexible cable connecting the connector of the printed wiring board of the optical pickup unit and the connector of the main printed wiring board is set. To provide an optical disc apparatus having a flat flexible cable that can be set optimally and can reduce distortion of a signal waveform between a connector of a printed wiring board of an optical pickup unit and a connector of a main printed wiring board. With the goal.

  In order to achieve the above object, the invention of claim 1 has a configuration in which a connector of a printed wiring board of an optical pickup unit and a connector of a main printed wiring board are connected by a flat flexible cable. In an optical disc apparatus for reproducing or recording / reproducing information, the flat flexible cable is formed in a substantially S-shape when viewed from the side so that the printed wiring board of the optical pickup unit can move in the radial direction of the optical disc. A movable line portion having one end of the substantially S-shaped cable connected to the connector of the printed circuit board of the optical pickup unit, one end connected to the other end of the movable line portion, and the other end With a fixed line part connected to the connector of the main printed wiring board When forming a bent portion between one end and the other end of the fixed line portion, the bending angle of the bent portion is optimally set so that a change in characteristic impedance of the transmission line at the bent portion can be reduced. Thus, an optical disc apparatus is provided in which the fixed line portion is wired at a predetermined location in the apparatus.

  In this configuration, when the printed wiring board of the optical pickup unit moves in the radial direction of the optical disk, the substantially line-shaped portion of the movable line portion of the flat flexible cable is deformed and follows the printed wiring board. The fixed line portion of the flat flexible cable has a bent portion, and connects the movable line portion and the main printed wiring board. Since the bent portion is set to a bending angle that can reduce the change in the characteristic impedance of the transmission line, even the bent portion reduces the amount of signal reflection and reduces signal waveform distortion. Can be made.

  According to this configuration, the bending angle of the bent portion of the flat flexible cable connecting the connector of the printed wiring board of the optical pickup unit and the connector of the main printed wiring board is optimally set, and the printed wiring board of the optical pickup unit is set. Can provide an optical disk device having a flat flexible cable that can reduce the distortion of the signal waveform between the connector of the main printed circuit board and the connector of the main printed circuit board. Therefore, the control accuracy of the control circuit can be improved and the control stability can be increased. Therefore, it is possible to provide a highly reliable optical disc apparatus.

  In the invention of claim 2, in the invention of claim 1, since the folding angle of the bent portion is set to 45 degrees or less, the signal input to the bent portion is less reflected and the waveform distortion of the signal is also reduced. To do.

  According to a third aspect of the present invention, in the first or second aspect of the present invention, since at least two bent portions are formed between one end and the other end of the fixed line portion, the printed wiring board of the optical pickup unit is provided. Even when the main printed wiring board is arranged on the side of the loader unit including the connector of the printed wiring board of the optical pickup unit and the connector of the main printed wiring board can be connected.

  As described above, according to the present invention, the optical pickup unit is configured by optimally setting the bending angle of the bent portion of the flat flexible cable connecting the connector of the printed wiring board of the optical pickup unit and the connector of the main printed wiring board. An optical disc apparatus having a flat flexible cable capable of reducing distortion of a signal waveform between the connector of the printed wiring board and the connector of the main printed wiring board can be provided. The control accuracy of the control circuit mounted on the wiring board can be improved and the control stability can be increased. Therefore, it is possible to provide a highly reliable optical disc apparatus.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a diagram for explaining a wiring state of an FFC (flat flexible cable) that connects a printed wiring board of an optical pickup unit provided in a loader unit and a main printed wiring board in an optical disc apparatus according to an embodiment of the present invention. It is the simplified board | substrate layout figure. FIG. 2 illustrates the wiring state of the fixed line portion excluding the movable line portion of the FFC that connects the printed wiring board of the optical pickup unit provided in the loader section and the main printed wiring board in the optical disk apparatus of the present embodiment. It is the simplified board | substrate layout figure for. FIG. 7 is a simplified configuration diagram for explaining a state in which the printed wiring board of the optical pickup unit and the movable line portion of the FFC are viewed from the side. In this embodiment, the FFC bending angle is set to 45 degrees. However, the present invention is not limited to this, and similar effects can be obtained as long as the angle is 45 degrees or less.

  1 and 2, the connector 6 of the printed wiring board 4 of the optical pickup unit in the loader unit 1 in the optical disk apparatus A is connected to the connector 7 of the main printed wiring board 2 via the FFC 3 having a plurality of signal lines. Has been. 1, 2, and 7, the loader unit 1 is provided with a printed wiring board 4 of an optical pickup unit on which an optical pickup (not shown) is mounted. The printed wiring board 4 of the optical pickup unit is a thread (not shown). The mechanism is configured to move in the vertical direction (disk radial direction) as seen from the drawing along the guide rail 5. One end 31 of the FFC 3 is connected to the connector 6 of the printed wiring board 4 of the optical pickup unit. The other end 32 of the FFC 3 is connected to the connector 7 of the main printed wiring board 2.

  In FFC3 shown in FIG. 1 and FIG. 7, a represents one point on the one end 31 side of the substantially S-shaped movable line portion 3a of FFC3, b represents one point of a bent portion of the movable line portion 3a of FFC3, and c represents FFC3. One point of the boundary between the movable line portion 3a and the fixed line portion 3b is shown.

  In the fixed line portion 3b of the FFC 3 shown in FIG. 2, it is bent along the side between the points m and e so that ∠α becomes 45 degrees, and the point f so that よ う α becomes 45 degrees. The fixed line portion 3b of the FFC 3 including these bent portions R1 and R2 is wired at a predetermined location in the optical disc apparatus A. In FIG. 2, the movable line portion of the FFC 3 is not shown for easy understanding of the shape of the fixed line portion 3 b of the FFC 3.

  FIG. 3 shows an FFC including a bend portion of the fixed line portion in the FFC for explaining a signal flow when the bend angle of the bend portion of the fixed line portion in the FFC is set to 45 degrees in the optical disc apparatus of the present embodiment. It is a figure which shows a part.

  As shown in FIG. 3, in the fixed line portion 3b of the FFC 3, when the signal S1 flows through a certain signal line, the direction of the flow is changed by 45 degrees. In this case, the transmission line in the bent portion L The abrupt change of the pattern is eliminated, and the characteristic impedance of the transmission line is reduced. That is, when the bending angle of the bent portion L is 45 degrees, the amount of reflection with respect to the signal S1 is reduced at the bent portion L, thereby reducing crosstalk and reducing the distortion of the waveform of the signal S1. Therefore, the control accuracy of the control circuit mounted on the main printed wiring board 2 to which the signal S1 (the same applies to the signal S2) is input is improved, and the control stability is increased. In addition, if the control accuracy is improved, it is possible to expect elimination of countermeasure parts (resistors, inductors, capacitors) such as overshoot.

  FIG. 4 is a graph showing the relationship between the frequency of the signal input to the FFC having a 45-degree bent portion and the gain of the signal input to the FFC and output from the FFC. Here, it is assumed that one bent portion is provided in the FFC.

  In FIG. 4, the horizontal axis indicates the frequency of the signal input to the FFC having a 45-degree bent portion (the frequency of the signal output from the printed wiring board of the optical pickup unit), and the vertical axis indicates the input to the FFC. The gain level (dB) of the signal output from the FFC is shown. G2 is an FFC having a 45 degree bent portion with respect to the frequency of the signal input to the FFC having a 45 degree bent portion (the frequency of the signal output from the printed wiring board of the optical pickup unit). 6 is a line showing a change in gain of a signal output from the FFC via the FFC.

  According to this line G2, in the range where the frequency of the signal output from the printed wiring board of the optical pickup unit is low (0 Hz to 10 MHz), the output signal is connected to the main print via the FFC having a 45 degree bent portion. It shows that the gain when reaching the wiring board hardly changes. That is, in the range where the frequency of the signal output from the printed circuit board of the optical pickup unit is low (0 Hz to 10 MHz), even if the folding angle of the FFC bent portion is 45 degrees, the signal is reflected by the bent portion. It can be inferred that there is almost no flow.

  In addition, in the range where the frequency of the signal output from the printed circuit board of the optical pickup unit is relatively high (about 20 MHz to 80 MHz), the signal is slightly reflected at the bent portion where the FFC bending angle is 45 degrees. Thus, it can be seen that the gain of the signal when reaching the main printed wiring board is slightly increased. That is, in the range where the frequency of the signal output from the printed circuit board of the optical pickup unit is relatively high (about 20 MHz to 80 MHz), the folding angle of the FFC bent portion is 45 degrees. Although some reflection occurs at the portion, it can be estimated that the waveform distortion is reduced as compared with the case where the bending angle is 90 degrees.

  Furthermore, in the range where the frequency of the signal output from the printed circuit board of the optical pickup unit is high (90 MHz or higher), the signal is reflected at the bent portion where the FFC bending angle is 45 degrees, but the bending angle is 90 °. It can be seen that the gain of the signal when it reaches the main printed circuit board does not decrease so much because the amount of reflection is small compared to the case of the degree. That is, even when the frequency of the signal output from the printed wiring board of the optical pickup unit is high (90 MHz or higher), the bending angle of the FFC bent portion is 45 degrees, so that the signal has less waveform distortion. Can be guessed.

  As described above, according to the present embodiment, the bending angles of the bent portions R1 and R2 of the flat flexible cable 3 connecting the connector 6 of the printed wiring board 4 of the optical pickup unit and the connector 7 of the main printed wiring board 2 are as follows. Is set to 45 degrees, and the flat flexible cable 3 capable of reducing distortion of the signal waveform between the connector 6 of the printed wiring board 4 of the optical pickup unit and the connector 7 of the main printed wiring board 2 is provided. The optical disk device A can be provided, and thereby the control accuracy of the control circuit mounted on the main printed wiring board 2 can be improved, and the control stability can be increased. Therefore, it is possible to provide a highly reliable optical disc apparatus A.

  INDUSTRIAL APPLICABILITY The present invention is applicable to a flat flexible cable for connecting a connector of a printed wiring board of an optical pickup unit and a connector of a main printed wiring board in an optical disc apparatus such as a DVD player, a DVD recorder, a BD player, and a BD recorder. .

FIG. 4 is a simplified board layout diagram for explaining a wiring state of an FFC that connects a printed wiring board of an optical pickup unit provided in a loader unit and a main printed wiring board in an optical disc device according to an embodiment of the present invention. . In the optical disk apparatus according to the embodiment, the wiring state of the fixed line portion excluding the movable line portion of the FFC connecting the printed wiring board of the optical pickup unit provided in the loader portion and the main printed wiring board is simplified. FIG. In the optical disk apparatus of the embodiment, a part of the FFC including the bent portion of the fixed line portion in the FFC for explaining a signal flow when the bending angle of the bent portion of the fixed line portion in the FFC is set to 45 degrees. FIG. It is a graph which shows the relationship between the frequency of the signal input into FFC which has a 45 degree | times bending part, and the gain of the signal input into FFC and output from FFC. FIG. 9 is a simplified board layout diagram for explaining a wiring state of an FFC that connects a printed wiring board of an optical pickup unit provided in a loader unit and a main printed wiring board in a conventional optical disc apparatus. In the conventional optical disc apparatus, a simplified substrate for explaining the wiring state of the fixed line portion excluding the movable line portion of the FFC connecting the printed wiring board of the optical pickup unit provided in the loader portion and the main printed wiring board. FIG. It is the simplified block diagram for demonstrating the state which looked at the printed wiring board of the optical pick-up unit, and the movable line part of FFC from the side. In the conventional optical disc apparatus, a part of the FFC including the bent portion of the fixed line portion in the FFC for explaining the signal flow when the bending angle of the bent portion of the fixed line portion in the FFC is set to 90 degrees is shown. FIG. It is a graph which shows the relationship between the frequency of the signal input into FFC which has a 90 degree | times bending part, and the gain of the signal input into FFC and output from FFC.

Explanation of symbols

2 Main printed wiring board 3 Flat flexible cable (FFC)
3a Movable line part 3b Fixed line part 4 Printed circuit board 6 and 7 connector A of optical pickup unit Optical disk apparatus R1, R2 Bending part

Claims (3)

In an optical disc apparatus having a configuration in which a connector of a printed wiring board of an optical pickup unit and a connector of a main printed wiring board are connected by a flat flexible cable, and reproducing information or recording / reproducing information on an optical disc,
The flat flexible cable is
The printed wiring board of the optical pickup unit is formed in a substantially S shape when viewed from the side so that it can move in the radial direction of the optical disc, and one end of the substantially S-shaped cable is printed on the optical pickup unit. A movable line connected to the connector of the wiring board;
A fixed line portion having one end connected to the other end of the movable line portion and the other end connected to a connector of the main printed wiring board;
When a bent part is formed between one end and the other end of the fixed line part, the bending angle of the bent part is optimized so as to reduce the change in the characteristic impedance of the transmission line at the bent part. An optical disc apparatus characterized in that the fixed line portion is set and wired at a predetermined location in the apparatus.   2. The optical disc apparatus according to claim 1, wherein a bending angle of the bent portion is set to 45 degrees or less.   3. The optical disc apparatus according to claim 1, wherein at least two bent portions are formed between one end and the other end of the fixed line portion.

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