JP2006309574A - Information processing apparatus and optical signal transmission medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To transmit an optical signal for connecting two housings rotatably coupled by a joined body, a signal processing unit provided in a first housing, and a signal processing unit provided in a second housing. An information processing apparatus including a medium suppresses twisting of an optical signal transmission medium accompanying a change in relative angle between the two casings.
SOLUTION: An optical signal transmission medium 116 for connecting a first signal processing unit 4 provided in a first housing 1 and a second signal processing unit 5 provided in a second housing 2 is included. In the information processing apparatus, the configuration of the optical signal transmission medium 116 is inserted into the connection body 120 provided inside the hinge unit 10, the first optical fiber 121 inserted into the connection body 120, and the connection body 120. A second optical fiber 122 that is in contact with the first optical fiber 121, and a connection body 120 rotatably connects the first optical fiber 121 and the second optical fiber 122; To do.
[Selection] Figure 1

Description

  The present invention relates to an optical signal transmission medium and an information processing apparatus including the optical signal transmission medium.

  In a notebook computer, a first housing provided with a computer main body and a keyboard exposed on the surface and a second housing provided with a display are rotatably coupled by a joined body. Yes. The first housing and the second housing rotate with respect to the joined body as a center, and the relative angle between the first housing and the second housing can be changed. Specifically, when the first casing is placed on a desk or the like, the first casing and the second casing are arranged so that the keyboard of the first casing and the display of the second casing face each other. The second housing is at a predetermined angle with respect to the first housing so that keyboard input can be performed while viewing the display from a state in which the housing is arranged in parallel (closed state). It can be changed to an arranged state (open state).

  Usually, the first casing and the second casing have protruding portions, and the joined body continuously penetrates the protruding portion of the first casing and the protruding portion of the second casing. It is provided to do. In addition, the protrusion part and connection body of a 1st housing | casing and a 2nd housing | casing are generally named a "hinge part" generally.

  The image displayed on the display provided in the second housing is generated based on the image information signal. The image information signal is an electrical signal and is generated by a CPU (central processing unit), a GPU (image information processing apparatus), or the like in the main body provided in the first housing. Therefore, the image information signal must be transmitted from the CPU or GPU in the first casing to the display in the second casing, and the conventional node book computer is provided with a signal transmission section.

  The signal transmission part is normally comprised by the electrical conducting wire. In order to increase the transmission speed of an image information signal, a technique using an electric conductor whose impedance is matched with a CPU, GPU, or display is known. However, in this case, it is necessary to use a thick electric lead represented by a coaxial cable, which hinders downsizing of the apparatus and prevents smooth opening and closing of the first casing and the second casing. Or Therefore, in general, a technique is used in which a plurality of thin electric conductors not matched in impedance are provided to effectively increase the transmission speed of the image information signal by parallel transmission (for example, Non-Patent Document 1). reference). According to this technique, the transmission speed can be effectively increased, but since the impedance is not matched, electrical noise is mixed in the image information signal. In addition, since the transmission speed is determined by the number of thin electric conductors, if the increase in speed is to be promoted, the hinge portion must be enlarged, which hinders downsizing of the device, while the size of the hinge portion is large. If this is limited, the number of electrical conductors must be reduced, which hinders an increase in transmission speed.

  In order to prevent inconveniences when the signal transmission unit is formed of an electrical lead, a technique for converting an image information signal into an optical signal using an optical fiber and transmitting the signal is proposed. Hereinafter, the case where an optical fiber is used will be described with reference to the drawings.

  FIGS. 7A and 7B are schematic perspective views showing a structural example of a conventional notebook computer. FIG. 7A shows a state in which the notebook computer is opened, and FIG. 7B shows a state in which the notebook computer is closed. In FIG. 7A, the internal structure is represented by a broken line.

  As shown in FIGS. 7A and 7B, the conventional notebook computer includes a first housing 1 having a protrusion 11, a second housing 2 having a protrusion 12, 1 includes a joined body (shaft body) 3 that joins the housing 1 to the second housing 2. FIG. 7 (a) shows an opened state and a diagram by the hinge portion 10 including the joined body, the protruding portion 11 of the first casing 1, and the protruding portion 12 of the second casing 2. A closed state as shown in FIG. 7B can be realized.

  The first housing 1 is provided with a first signal processing unit 4 having an arithmetic processing device such as a CPU or GPU, an information input device such as a keyboard, and an information storage device such as a memory. The second housing 2 is provided with a second signal processing unit 5 such as an image display device (display). The first signal processing unit 4 further includes a first optical signal converter (optical transmitter) 14 that converts an electrical signal into an optical signal and transmits the optical signal, and the second signal processing unit 4 includes an optical signal. A second optical signal converter (optical receiver) 15 that receives the signal and converts the optical signal into an electrical signal is further included. The first optical signal converter 14 and the second optical signal converter 15 are connected by an optical fiber (optical signal transmission medium) 16 that passes through the hinge 10.

  The image information signal generated by the first signal processing unit 4 is temporarily converted from an electrical signal to an optical signal by the first optical signal converter 14 and transmitted to the optical receiver 15 through the optical fiber. The signal is reconverted into an electrical signal by the optical receiver 15, whereby the image information signal is input to the second signal processing unit.

  Since the optical fiber 16 that is thinner than the electrical lead such as a coaxial cable is used, the hinge portion can be downsized and the transmission speed of the image information signal can be increased. Further, as in the case of the electrical conductor, it is not necessary to match the impedance, and mixing of electrical noise into the image information signal can be suppressed.

FIG. 8 is a schematic perspective view showing the shape change of the optical signal transmission medium in the open / close state of the conventional information processing apparatus. In FIG. 8, the shape of the optical fiber 16 in the closed state is represented by a broken line, and the shape of the optical fiber 16 in the opened state is represented by a one-dot chain line. In response to a change in the relative angle between the first housing 1 and the second housing 2, the optical fiber 16 was twisted. In particular, in the optical fiber 16, a strong torsional stress was generated at a portion located inside the hinge portion 10 (see FIG. 1).
International Business Machines Corporation, “ThinkPad X30 / X31 (MT 2672/2673/2884/2885/2890/2891) ThinkPad Dock and ThinkPad Dock II (MT 2631) ThinkPad Dock III (MT 2877) Maintenance Manual”, [online], Heisei February 2016, IBM Japan, 105 pages, [Search on July 26, 2004], Internet <http://www-6.ibm.com/jp/pc/home/manual/0402/a8883103.pdf>

  When the optical fiber is twisted as in the prior art, the transmission efficiency of the optical signal in the optical fiber (the rate at which the optical signal is normally transmitted) decreases. Further, when the optical fiber is repeatedly twisted with the opening and closing of the two housings, the optical signal transmission efficiency is reduced even when the optical fiber is damaged. In addition, once the optical fiber is damaged, the transmission efficiency of the optical signal is lowered regardless of the presence or absence of twisting. Further, when damage has accumulated, it sometimes leads to disconnection.

  Accordingly, in the present invention, in the optical signal transmission medium, the optical signal transmission efficiency is improved by reducing the twist of the optical signal transmission medium when an external force that twists both ends is applied.

  According to the present invention, in the information processing apparatus including the optical signal transmission medium that connects the signal processing unit provided in the first housing and the signal processing unit provided in the second housing, By reducing the twist of the optical signal transmission medium due to the change in the relative angle between the housing and the second housing, the transmission efficiency of the optical signal in the optical signal transmission medium is improved. In addition, the durability of the optical signal transmission medium is improved by reducing the twist of the optical signal transmission medium. Thereby, the performance and durability of the information processing apparatus are improved.

  In order to solve the above problems, an information processing apparatus according to the present invention rotatably couples a first housing, a second housing, a first housing, and a second housing. A combined body, a first signal processing unit provided in the first housing and having the first optical signal converter, and a second signal provided in the second housing and having the second optical signal converter. The signal processing unit, the combined body, the first housing with the vicinity of the combined body and the second housing with the vicinity of the combined body as hinges, and the first light through the inside of the hinges. An information processing apparatus including an optical signal transmission medium for connecting a signal converter and a second optical signal converter, wherein the optical signal transmission medium is provided inside the hinge portion and has a through hole; A first optical fiber having one end inserted into the through hole of the connection body and the other end connected to the first optical signal converter, and one end penetrating the connection body. A second optical fiber inserted into the hole to contact the first optical fiber and having the other end connected to the second optical signal converter, and the connection body includes the first optical fiber and the second optical fiber. The optical fiber is rotatably connected, and the first optical fiber and the second optical fiber are relatively rotated in accordance with a change in the relative angle between the first housing and the second housing. It is characterized by.

  In order to solve the above problems, an optical signal transmission medium according to the present invention includes a connection body having a through hole, a first optical fiber having one end inserted into the through hole of the connection body, and one end having a connection body. A second optical fiber that is inserted into the through-hole and is in contact with the first optical fiber, and the connection body rotatably connects the first optical fiber and the second optical fiber. .

  In the information processing apparatus according to the present invention, two optical fibers (first optical fiber) that are rotatably connected are used as an optical signal transmission medium that connects the first optical signal converter and the second optical signal converter. And the second optical fiber), the twist of the optical signal transmission medium due to the change in the relative angle between the first housing and the second housing can be suppressed, and the hinge portion is enlarged. Thus, the signal transmission efficiency can be improved. In addition, since the twist of the optical signal transmission medium can be suppressed, occurrence of disconnection of the optical signal transmission medium can be suppressed. This improves the performance and durability of the information processing apparatus.

  In the case of the optical signal transmission medium according to the present invention, the two optical fibers rotate relatively even if they are subjected to an external force that causes a twist between the two optical fibers (the first optical fiber and the second optical fiber). Therefore, the twist of the optical signal transmission medium can be suppressed.

  An information processing apparatus according to the present invention will be described with reference to the drawings. FIG. 1 is a schematic perspective view illustrating a structural example of an information processing apparatus. FIG. 1 shows a case where the internal structure is seen through.

  The information processing apparatus includes a first housing 1, a second housing 2, and a joined body 3 that joins the first housing 1 and the second housing 2 rotatably. In general, a portion in the vicinity of the joined body 3 in the first housing 1 (protruding portion 11 in FIG. 1), and a portion in the vicinity of the joined body 3 in the second housing 2 (protruding portion 12 in FIG. 1). ) And the joined body 3 are collectively referred to as a “hinge part”. The first casing 1 is provided with a first signal processing unit 4 having a first optical signal converter 14, and the second casing 2 is provided with a second optical signal converter 15. Two signal processing units 5 are provided. The first optical signal converter 14 and the second optical signal converter 15 are connected by an optical signal transmission medium 116.

  The information processing apparatus according to the present invention may have the same configuration as any known information processing apparatus except that the optical signal transmission medium 116 according to the present invention is used. Examples of the information processing apparatus include a notebook computer, a PDA (personal data access), and a mobile phone.

  One of the first optical signal converter 14 and the second optical signal converter 15 connected by the optical signal transmission medium 116 is a device that converts an electrical signal into an optical signal, and the other converts an optical signal into an electrical signal. It may be a device that performs. In this case, unidirectional signal transmission from the first signal processing unit 4 to the second signal processing unit 5 can be performed. Further, both the first optical signal converter 14 and the second optical signal converter 15 may be devices that perform conversion from an electrical signal to an optical signal and conversion from an optical signal to an electrical signal. In this case, bidirectional signal transmission can be performed between the first signal processing unit 4 and the second signal processing unit 5.

  The first signal processing unit 4 and the second signal processing unit 5 include at least one device that functions based on an electrical signal. Examples of such devices include arithmetic processing devices such as CPUs and GPUs, information input devices such as keyboards, image display devices, information storage devices such as memories and hard disks, imaging devices such as CCD cameras, and radio wave transmission / reception devices. Is mentioned.

  The optical signal transmission medium 116 includes a connection body 120, a first optical fiber 121, and a second optical fiber 122. FIG. 2 is a schematic perspective view showing a structural example of the optical signal transmission medium partially enlarged. FIG. 2 shows only the vicinity of the connection body. As shown in FIG. 2, a part of the first optical fiber 121 and the second optical fiber 121 is inserted into the through hole of the connection body 120, and the connection body 120 is connected to the first optical fiber 121. And the second optical fiber 122 are rotatably connected. The end surface of the first optical fiber 121 and the end surface of the second optical fiber 122 are in contact with each other in the through hole of the connection body 120. Here, to connect the first optical fiber 121 and the second optical fiber 122 so as to be freely rotatable, the first optical fiber 121 and the second optical fiber 122 are connected so as to be relatively rotatable. Means. Note that only the first optical fiber 121 may rotate with respect to the connection body 120, only the second optical fiber 122 may rotate, or both of them may rotate.

  The first optical fiber 121 and the second optical fiber 122 are relative to each other according to a change in the relative angle between the first housing 1 (see FIG. 1) and the second housing 2 (see FIG. 1). Therefore, the occurrence of twisting of the optical signal transmission medium 116 is suppressed. Thereby, the transmission efficiency and durability of the optical signal transmission medium are improved, and as a result, the performance and durability of the information processing apparatus are improved.

  The connection body 120 is provided inside the hinge portion 10 (see FIG. 1). The connection body 120 may be located only in one of the first housing 1 and the second housing 2, or may be located over both the first housing and the second housing. . Moreover, it may be arrange | positioned at the outer edge of the coupling body 3 (refer FIG. 1), and when the coupling body 3 is a cylindrical shaft body, it may be provided inside the cylindrical shaft body. . Furthermore, although the coupling body 3 which is a cylindrical shaft body is illustrated in FIG. 1, the coupling body in the present invention may be a single sphere or a plurality of spheres arranged on a straight line.

  FIG. 2 illustrates the case where the connecting body 120 has a cylindrical shape that generally has a crack along the axial direction (generally referred to as a split sleeve). In general, it may be referred to as a sleeve), or may be a cylindrical shape partially having a crack along the axial direction. The external shape of the connection body 120 may be any other shape.

  When the connection body 120 has a crack, the first optical fiber 121 and / or the second optical fiber 122 is inserted into the connection body 120 in order to increase the inner diameter of the portion of the connection body 120 having the crack. Becomes easier. Furthermore, the first optical fiber 121 and / or the second optical fiber 122 can be detachably attached to the connection body 120. In the insertion of the first optical fiber 121 and / or the second optical fiber 122 into the connection body 120, the first optical fiber 121 and / or the second optical fiber 122 may be inserted along the axial direction of the through hole of the connection body 120. You may insert from a crack.

  Here, the structure of the optical signal transmission medium will be described in more detail. FIG. 3 is a schematic cross-sectional view partially showing a structural example of the optical signal transmission medium. In FIG. 3, only the vicinity of the connection body is shown. The optical signal transmission medium preferably satisfies the following conditions as shown in FIG.

  (Condition 1) In the portion where the first optical fiber 121 is inserted into the connection body 120, the small outer diameter portion 171 and the first optical fiber 121 and the second optical fiber 122 from the small outer diameter portion 171 A large outer diameter portion 172 is formed on the side close to the contact surface and has an outer diameter larger than the outer diameter of the small outer diameter portion 171.

  (Condition 2) In the portion where the second optical fiber 122 is inserted into the connection body 120, the small outer diameter portion 181, and the first optical fiber 121 and the second optical fiber 122 from the small outer diameter portion 181. A large outer diameter portion 182 is formed on the side close to the contact surface and has an outer diameter larger than the outer diameter of the small outer diameter portion 181.

  (Condition 3) The connection body 120 includes a large inner diameter portion 130 into which the large outer diameter portion 172 of the first optical fiber 121 and the large outer diameter portion 182 of the second optical fiber 122 are inserted, and the first optical fiber 121. The small outer diameter portion 171 is inserted, the first small inner diameter portion 131 having an inner diameter smaller than the inner diameter of the large inner diameter portion 130, and the small outer diameter portion 181 of the second optical fiber 122 are inserted. And a second small inner diameter portion 132 having an inner diameter smaller than the inner diameter.

  (Condition 4) The outer diameter of the large outer diameter portion 172 in the first optical fiber 121 is larger than the inner diameter of the first small inner diameter portion 131 in the connection body 120, and the large outer diameter portion 172 in the first optical fiber 121 The step surface between the small outer diameter portion 171 is in contact with the step surface between the large inner diameter portion 130 and the first small inner diameter portion 131 in the connection body 120.

  (Condition 5) The outer diameter of the large outer diameter portion 182 in the second optical fiber 122 is larger than the outer diameter of the second small inner diameter portion 132 in the connector 120, and the large outer diameter portion 182 in the second optical fiber 122. And the small outer diameter portion 181 are in contact with the step surface between the large inner diameter portion 130 and the second small inner diameter portion 132 in the connection body 120.

  When all the above conditions are satisfied, the first optical fiber 121 and the second optical fiber 122 are detached from the connection body 120 due to an external force resulting from a change in the relative angle between the first housing and the second housing. This can be prevented, and the end face of the first optical fiber 121 and the end face of the second optical fiber 122 can be reliably brought into contact with each other.

  In FIG. 3, the inclination angle of the step surface between the large outer diameter portion 172 and the small outer diameter portion 171 and the inclination angle of the step surface between the large inner diameter portion 130 and the first small inner diameter portion 131 are the same. In this example, the step surfaces are substantially in contact with each other. However, the step surfaces have different inclination angles and shapes, and the step surfaces are only partially in contact. It may be. Similarly, the step surface between the large outer diameter portion 182 and the small outer diameter portion 181 and the step surface between the large inner diameter portion 130 and the second small inner diameter portion 132 are substantially in contact with each other. You may contact only in part.

  As shown in FIG. 3, the tips of the first optical fiber 121 and the second optical fiber 122 are preferably tapered. This is because the first optical fiber 121 and the second optical fiber 122 can be easily inserted into the connection body 120 in this case.

  In the case where the small outer diameter portion 171 and the large outer diameter portion 172 are formed in the first optical fiber 121, the first optical fiber 121 includes the core 141 and the cladding layer 151 formed on the periphery of the core 141. A protective layer 161 formed on the periphery of the cladding layer 151, the outer diameter of the core 141 is substantially uniform, the thickness of the cladding layer 151 is substantially uniform, and the thickness of the protective layer 161 Are preferably different between the large outer diameter portion 172 and the small outer diameter portion 171. Similarly, when forming the small outer diameter portion 181 and the large outer diameter portion 182 in the second optical fiber 122, the second optical fiber 122 includes the core 142 and the clad formed on the periphery of the core 142. A layer 152 and a protective layer 162 formed on the periphery of the cladding layer 152, the outer diameter of the core 142 is substantially uniform, the thickness of the cladding layer 152 is substantially uniform, and the protective layer The thickness of 162 is preferably different between the large outer diameter portion 182 and the small outer diameter portion 181.

  The first optical fiber 121 and the second optical fiber 122 are preferably pressed against each other with a predetermined pressure. This is because if the adhesion is poor, the transmission efficiency of the optical signal is lowered. However, if the contact pressure is too high, the relative rotation of the first optical fiber 121 and the second optical fiber 122 deteriorates, and the end faces may be damaged with the rotation. Therefore, the contact pressure is preferably optimized according to the material of the cores 141 and 142 and the material of the cladding layers 151 and 152.

  In FIG. 3, in the first optical fiber 121, the outer diameter of the small outer diameter portion 171 is the same as the outer diameter of the general outer shape (the outer diameter of the portion of the first optical fiber 121 that is not inserted into the connection body 120). However, it may be different from the outer diameter of the general outer shape. If the outer diameter of the small outer diameter portion 171 is the same as the outer diameter of the general outer shape, it is only necessary to form the protrusions that make up the large outer diameter portion 172, which facilitates manufacturing. Similarly, in the second optical fiber 122, the outer diameter of the small outer diameter portion 181 is the same as the outer diameter of the general outer shape (the outer diameter of the portion not inserted in the connection body 120 in the second optical fiber 122). Although it may be present or different, it is preferably the same as the outer diameter of the general outer shape.

  In FIG. 3, small outer diameter portions 171 and 181 and large outer diameter portions 172 and 182 are formed on both the first optical fiber 121 and the second optical fiber 122. It may be formed. In this case, it is preferable that the optical fiber in which the large outer diameter portion and the small outer diameter portion are not formed is fixed so as not to rotate with respect to the connection body 120. This is because good contact between the first optical fiber 121 and the second optical fiber 122 can be maintained.

  Here, another structural example of the optical signal transmission medium will be described. FIG. 4 is a schematic sectional view partially showing another structural example of the optical signal transmission medium. FIG. 4 shows only the vicinity of the connection body. As shown in FIG. 4, the optical signal transmission medium preferably satisfies the following conditions.

  (Condition 1) In a portion where the first optical fiber 221 is inserted into the connection body 220, the small outer diameter portion 271, and the first optical fiber 221 and the second optical fiber 222 from the small outer diameter portion 271. A first large outer diameter portion 272 having a larger outer diameter than the outer diameter of the small outer diameter portion 271 is formed on the side closer to the contact surface, and a smaller outer diameter is formed on the side farther from the contact surface than the small outer diameter portion 271. And a second large-diameter portion 273 having a larger outer diameter than the outer diameter of the portion 271.

  (Condition 2) In the portion where the second optical fiber 222 is inserted into the connection body 220, the small outer diameter portion 281, and the first optical fiber 221 and the second optical fiber 222 from the small outer diameter portion 281. A first large outer diameter portion 282 having a larger outer diameter than the outer diameter of the small outer diameter portion 281 is formed on the side close to the contact surface, and a smaller outer diameter is formed on the side farther from the contact surface than the small outer diameter portion 281. A second large outer diameter portion 283 having an outer diameter larger than the outer diameter of the portion 281.

  (Condition 3) The connecting body 220 is a first large inner diameter portion into which the first large outer diameter portion 272 of the first optical fiber 221 and the first large outer diameter portion 282 of the second optical fiber 222 are inserted. 230, the small outer diameter portion 271 of the first optical fiber 221 is inserted, the first small inner diameter portion 231 having an inner diameter smaller than the inner diameter of the first large inner diameter portion 230, and the second of the first optical fiber 221. The large outer diameter portion 273 is inserted, the second large inner diameter portion 232 having a larger inner diameter than the inner diameter of the first small inner diameter portion 231, and the small outer diameter portion 281 of the second optical fiber 222 are inserted. The second small inner diameter portion 233 having an inner diameter smaller than the inner diameter of the large inner diameter portion 230 and the second large outer diameter portion 283 of the second optical fiber 222 are inserted, and the inner diameter is smaller than the inner diameter of the second small inner diameter portion. A large third large inner diameter portion 234.

  (Condition 4) The outer diameter of the first large outer diameter portion 272 in the first optical fiber 221 is larger than the inner diameter of the first small inner diameter portion 231 in the connection body 220, and the first optical fiber 221 has the first outer diameter. The step surface between the large outer diameter portion 272 and the small outer diameter portion 271 is in contact with the step surface between the first large inner diameter portion 230 and the first small inner diameter portion 231 in the connection body 220.

  (Condition 5) The outer diameter of the first large outer diameter portion 282 in the second optical fiber 222 is larger than the inner diameter of the second small inner diameter portion 233 in the connection body 220, and the first optical fiber 222 has the first outer diameter. The step surface between the large outer diameter portion 282 and the small outer diameter portion 281 is in contact with the step surface between the first large inner diameter portion 230 and the second small inner diameter portion 233 in the connection body 220.

  (Condition 6) The outer diameter of the second large outer diameter portion 273 in the first optical fiber 221 is larger than the inner diameter of the first small inner diameter portion 231 in the connection body 220, and the second optical fiber 221 has the second diameter in the first optical fiber 221. The step surface between the large outer diameter portion 273 and the small outer diameter portion 271 is in contact with the step surface between the second large inner diameter portion 232 and the first small inner diameter portion 231 in the connection body 220.

  (Condition 7) The outer diameter of the second large outer diameter portion 283 in the second optical fiber 222 is larger than the inner diameter of the second small inner diameter portion 233 in the connection body 220, and the second optical fiber 222 has the second outer diameter. The step surface between the large outer diameter portion 283 and the small outer diameter portion 281 is in contact with the step surface between the third large inner diameter portion 234 and the second small inner diameter portion 233 in the connection body 220.

  When all the above conditions are satisfied, the first optical fiber 221 and the second optical fiber 222 are separated from the connection body 220 by an external force due to a change in the relative angle between the first housing and the second housing. The first optical fiber 221 and the second optical fiber 222 can be prevented from moving to the center side of the connection body 220 as well as being prevented from coming off. In other words, the end face of the first optical fiber 221 and the end face of the second optical fiber 222 can be reliably brought into contact with each other, and the pressure change in contact between the first optical fiber 221 and the second optical fiber 222 can be changed. Can be suppressed.

  In the case where the small outer diameter portion 271, the first large outer diameter portion 272, and the second large outer diameter portion 273 are formed in the first optical fiber 221, the outer diameter of the core 141 is substantially uniform. The thickness of the clad layer 151 is substantially uniform, the thickness of the protective layer 261 is different between the first large outer diameter portion 272 and the small outer diameter portion 271, and the thickness of the protective layer 261 is the second thickness. It is preferable that the large outer diameter portion 273 and the small outer diameter portion 271 are different. Similarly, when the small outer diameter portion 281, the first large outer diameter portion 282, and the second large outer diameter portion 283 are formed in the second optical fiber 222, the outer diameter of the core 142 is substantially equal. The thickness of the cladding layer 152 is substantially uniform, the thickness of the protective layer 262 differs between the first large outer diameter portion 282 and the small outer diameter portion 281, and the thickness of the protective layer 262 It is preferable that the second large outer diameter portion 283 and the small outer diameter portion 281 have different lengths.

  In FIG. 4, small outer diameter portions 271, 281, first large outer diameter portions 272, 282, and second large outer diameter portions 273, 274 are included in both the first optical fiber 221 and the second optical fiber 222. However, the irregularities may be formed only on one of the optical fibers. In this case, it is preferable to fix the optical fiber on which the unevenness is not formed so as not to rotate with respect to the connection body 220. This is because good contact between the first optical fiber 221 and the second optical fiber 222 can be maintained.

  FIG. 4 illustrates a case where the outer diameters of the first large outer diameter portion 272 and the second large outer diameter portion 273 in the first optical fiber 221 are the same as the outer diameter of the general outer shape. It may be different from the outer diameter of the general outer shape. When the outer diameters of the first large outer diameter portion 272 and the second large outer diameter portion 273 are the same as the outer diameter of the general outer shape, it is only necessary to form a recess that constitutes the small outer diameter portion 271. Since it is good, manufacture becomes easy. Similarly, in the second optical fiber 222, the outer diameters of the first large outer diameter portion 282 and the second large outer diameter portion 283 may be the same as or different from the outer diameter of the general outer shape. However, it is preferably the same as the outer diameter of the general outer shape.

  It is preferable that the first optical fiber 221 and the second optical fiber 222 are pressed against each other with a predetermined pressure. This is because if the adhesion is poor, the transmission efficiency of the optical signal is lowered.

  In the following, another structural example of the information processing apparatus according to the present invention will be described. FIG. 5 is a schematic perspective view partially showing an example of the structure in the vicinity of the optical signal transmission medium. In the information processing apparatus, when the first optical signal converter 14 and the second optical signal converter 15 cannot be arranged in the axial direction of the through hole of the connection body 120 as shown in FIG. Is common. In such a case, in the information processing apparatus according to the present invention, as shown in FIG. 5, the connection body 120 and the first optical signal converter 14 (see FIG. 1) inside the first housing 1 (see FIG. 1). 1), a first fiber guide 123 having a curved through hole, and a connection body 120 and a second optical signal converter inside the second casing 2 (see FIG. 1). 15 (see FIG. 1), and a second fiber guide 124 having a curved through hole is preferably further included. The first optical fiber 121 passes through the through hole of the first fiber guide 123, and the first fiber guide 123 is first fixed to the optical fiber 121. Similarly, the second optical fiber 122 passes through the through hole of the second fiber guide 124, and the second fiber guide 124 is fixed to the first optical fiber 122. In this case, the minimum curvature radii of the first optical fiber 121 and the second optical fiber 122 are respectively set to the first optical fiber 121 and the second optical fiber 122 even when receiving an external force accompanying a change in the relative angle between the first housing and the second housing. Since it can be regulated by the first fiber guide 123 and the second fiber guide 124, the transmission efficiency of the optical signal is further improved. In general, when the optical fiber is bent to a predetermined radius of curvature (critical radius) or less, the transmission efficiency of the optical signal is reduced. However, the first fiber guide 123 and the second fiber guide 124 cause the optical fiber to transmit less than the critical radius. This is because it can be regulated so that it does not become. 5 illustrates the case where the first fiber guide 123 and the second fiber guide 124 are provided, but only one of them may be provided.

  The curved shape of the through hole in the first fiber guide 123 is preferably determined in consideration of the position of the connection body 120 and the position of the first optical signal converter. Similarly, the curved shape of the through hole in the second fiber guide 124 is preferably determined in consideration of the position of the connection body 120 and the position of the second optical signal converter. For example, in the first optical fiber 121, a portion between the connection body 120 and the first fiber guide 123 is arranged substantially linearly, and the first fiber guide 123 and the first optical signal converter are connected to each other. It is preferable to optimize the curved shape of the through hole in the first fiber guide 123 so that the portion in between is arranged substantially linearly.

  Here, a modification of the fiber guide will be described. FIG. 6 is a schematic perspective view showing another structural example of the fiber guide. As shown in FIG. 6, the second fiber guide 124 may have a curved cylindrical shape (split fiber guide) having a crack. When the second fiber guide 124 has a crack, the inner diameter of the second fiber guide 124 can be increased, so that the second optical fiber 122 can be easily attached. Furthermore, the second optical fiber 122 can be detachably attached to the second fiber guide 124. Note that the second optical fiber 122 may be mounted along the axial direction of the curved through hole in the second fiber guide 124 or may be mounted from the crack of the first fiber guide 124. Good. Similarly, the first fiber guide 123 (see FIG. 5) may have a curved cylindrical shape having a crack. In the following, FIG. 5 will be referred to again.

  In the information processing apparatus according to the present invention, each of the first fiber guide 123 and the second fiber guide 124 preferably has a curved cylindrical shape (split fiber guide) having a crack.

  In the information processing apparatus according to the present invention, the first fiber guide 123 is fixed to the first casing 1 (see FIG. 1), and the second fiber guide 124 is fixed to the second casing 2 (see FIG. 1). ) Is preferably fixed. In this case, it is because the external force resulting from the change in the relative angle between the first housing and the second housing can be concentrated between the first fiber guide 123 and the second fiber guide 124. . By the relative rotation of the first optical fiber 121 and the second optical fiber 122, the twist of the optical signal transmission medium can be well mitigated.

  However, if the central axis of the connection body 120 and the central axis (rotation axis of the casing) of the joined body 3 (see FIG. 1) do not coincide with each other, the relative angle between the first casing and the second casing The position of the end face of the first fiber guide 124 and the end face of the second fiber guide 124 change relative to each other. Accordingly, in order to prevent the first optical fiber 121 and the second optical fiber 122 from coming out of contact with each other due to the change, the connection between the connection body 120 and the first fiber guide 123 in the first optical fiber 121 is avoided. The portion and / or the portion of the second optical fiber 122 between the connector 120 and the second fiber guide 124 must be slackened.

  Also, a first fiber guide 123 fixed to the first housing and a second fiber guide 124 fixed to the second housing are provided, and the center axis of the joined body and the through hole of the connecting body are provided. When the connection body is arranged so as to coincide with the central axis, the first optical fiber 121, the end face of the first optical fiber 121 and the end face of the second optical fiber 122 can be positioned precisely. The second optical fiber 122 and the connection body 120 do not have to be formed with unevenness as shown in FIGS. In this case, the connection body 120 is preferably fixed to the joined body.

  In the above description, as illustrated in FIG. 1, the case where the first casing 1 and the second casing 2 rotate so as to be folded or unfolded has been described. On the other hand, the structure which rotates to the right and left so that a 2nd housing | casing shakes a head may be sufficient.

  Since the optical signal transmission medium according to the present invention has the same configuration as the optical signal transmission medium used in the information processing apparatus according to the present invention, detailed description thereof is omitted. The optical signal transmission medium according to the present invention can be used for other than the information processing apparatus.

  INDUSTRIAL APPLICABILITY The present invention can be used to suppress a decrease in optical signal transmission efficiency in an optical signal transmission medium.

  In addition, the present invention can be used in an information processing apparatus to suppress twisting of an optical signal transmission medium accompanying a change in the relative angle between two housings. That is, it can be used to improve the performance and durability of the information processing apparatus.

FIG. 1 is a schematic perspective view showing a structural example of an information processing apparatus according to the present invention. FIG. 2 is a schematic perspective view partially showing a structural example of the optical signal transmission medium in the information processing apparatus according to the present invention. FIG. 3 is a schematic cross-sectional view partially showing a structural example of the optical signal transmission medium in the information processing apparatus according to the present invention. FIG. 4 is a schematic sectional view partially showing another structural example of the optical signal transmission medium in the information processing apparatus according to the present invention. FIG. 5 is a schematic perspective view showing an example of the structure of the fiber guide in the information processing apparatus according to the present invention. FIG. 6 is a schematic perspective view showing another structure example of the fiber guide in the information processing apparatus according to the present invention. 7A and 7B are schematic perspective views showing a structural example of a conventional information processing apparatus. FIG. 8 is a schematic perspective view showing the shape change of the optical signal transmission medium in the open / close state of the conventional information processing apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 1st housing | casing 2 2nd housing | casing 3 joined body (shaft body)
4 Signal Processing Unit 5 Signal Processing Unit 10 Hinge Unit 11 Protruding Portion (portion in the vicinity of the joined body in the first housing)
12 Protrusion (part near the joined body in the second housing)
14 1st optical signal conversion part 15 2nd optical signal conversion part 16 Optical fiber (optical signal transmission medium)
116 Optical signal transmission medium 120 Connector 121, 221 First optical fiber 122, 222 Second optical fiber 123 First fiber guide 124 Second fiber guide 130 Large inner diameter portion 131 First small inner diameter portion 132 Second Small inner diameter portion 141,142 core 151,152 clad layer 161,162,261,262 protective layer 171,181 small outer diameter portion 172,182 large outer diameter portion 271,281 small outer diameter portion 272,282 first large Outer diameter portion 273, 283 Second large outer diameter portion 230 First large inner diameter portion 231 First small inner diameter portion 232 Second large inner diameter portion 233 Second small inner diameter portion 234 Third large inner diameter portion

Claims (11)

A first housing;
A second housing;
A joined body that rotatably couples the first housing and the second housing;
A first signal processing unit provided in the first housing and having a first optical signal converter;
A second signal processing unit provided in the second casing and having a second optical signal converter;
The first light passes through the inside of the hinge portion, with the combined portion, a portion in the vicinity of the combined body in the first housing and a portion in the vicinity of the combined body in the second housing as a hinge portion. An information processing apparatus including an optical signal transmission medium that connects a signal converter and the second optical signal converter,
The optical signal transmission medium is provided inside the hinge portion, has a through hole, one end is inserted into the through hole of the connection body, and the other end is connected to the first optical signal converter. A first optical fiber, one end of which is inserted into the through-hole of the connection body and is in contact with the first optical fiber, and the other end is connected to the second optical signal converter. With optical fiber,
The connection body rotatably connects the first optical fiber and the second optical fiber;
Information processing characterized in that the first optical fiber and the second optical fiber rotate relative to each other in accordance with a change in the relative angle between the first housing and the second housing. apparatus.   The information processing apparatus according to claim 1, wherein the connection body has a cylindrical shape having a crack. In the portion where the first optical fiber is inserted into the connection body, a small outer diameter portion, and a side closer to the contact surface between the first optical fiber and the second optical fiber than the small outer diameter portion A large outer diameter portion having an outer diameter larger than the outer diameter of the small outer diameter portion,
In the portion where the second optical fiber is inserted into the connection body, a small outer diameter portion is formed on the side closer to the contact surface than the small outer diameter portion, and is outside the outer diameter of the small outer diameter portion. A large outer diameter portion having a large diameter,
The connecting body includes a large inner diameter portion into which the large outer diameter portion of the first optical fiber and the large outer diameter portion of the second optical fiber are inserted, and the small outer diameter of the first optical fiber. A first small inner diameter portion having an inner diameter smaller than the inner diameter of the large inner diameter portion and the smaller outer diameter portion of the second optical fiber are inserted, and the first inner diameter portion smaller than the inner diameter of the large inner diameter portion is inserted. 2 small inner diameter parts,
An outer diameter of the large outer diameter portion in the first optical fiber is larger than an inner diameter of the first small inner diameter portion in the connection body, and the large outer diameter portion and the small outer diameter in the first optical fiber. A step surface between the contact portion and the step surface between the large inner diameter portion and the first small inner diameter portion of the connection body,
An outer diameter of the large outer diameter portion in the second optical fiber is larger than an inner diameter of the second small inner diameter portion in the connection body, and the first large outer diameter portion in the second optical fiber and the The information processing apparatus according to claim 1, wherein a step surface between the small outer diameter portion is in contact with a step surface between the large inner diameter portion and the second small inner diameter portion in the connection body. Each of the first optical fiber and the second optical fiber has a core, a cladding layer formed on the periphery of the core, and a protective layer formed on the periphery of the cladding layer,
In the first optical fiber, the outer diameter of the core is substantially uniform, the thickness of the cladding layer is substantially uniform, and the thickness of the protective layer is the same as that of the large outer diameter portion and the Unlike the small outer diameter part,
In the second optical fiber, the outer diameter of the core is substantially uniform, the thickness of the cladding layer is substantially uniform, and the thickness of the protective layer is the same as that of the large outer diameter portion and the The information processing apparatus according to claim 4, wherein the information processing apparatus is different from the small outer diameter portion. In the portion where the first optical fiber is inserted into the connection body, a small outer diameter portion, and a side closer to the contact surface between the first optical fiber and the second optical fiber than the small outer diameter portion A first large outer diameter portion having an outer diameter larger than an outer diameter of the small outer diameter portion, and formed on a side farther from the contact surface than the small diameter portion, and outside the outer diameter of the small outer diameter portion. A second large diameter portion having a large diameter,
In the portion where the second optical fiber is inserted into the connection body, a small outer diameter portion is formed on the side closer to the contact surface than the small outer diameter portion, and is outside the outer diameter of the small outer diameter portion. A first large outer diameter portion having a large diameter, and a second large outer diameter portion formed on a side farther from the contact surface than the small outer diameter portion and having an outer diameter larger than the outer diameter of the small outer diameter portion. Have
The connecting body includes a first large inner diameter portion into which the first large outer diameter portion of the first optical fiber and the first large outer diameter portion of the second optical fiber are inserted; A first small inner diameter portion having an inner diameter smaller than an inner diameter of the first large inner diameter portion; and the second large outer diameter portion of the first optical fiber. Is inserted, the second large inner diameter portion having an inner diameter larger than the inner diameter of the first small inner diameter portion, and the small outer diameter portion of the second optical fiber are inserted, and the inner diameter of the first large inner diameter portion is inserted. A second small inner diameter portion having a smaller inner diameter and the second large outer diameter portion of the second optical fiber are inserted, and a third large inner diameter portion having an inner diameter larger than the inner diameter of the second small inner diameter portion. And
An outer diameter of the first large outer diameter portion in the first optical fiber is larger than an inner diameter of the first small inner diameter portion in the connection body, and the first large outer diameter in the first optical fiber. A step surface between the first outer diameter portion and the first outer diameter portion of the connecting body is in contact with the step surface between the first larger inner diameter portion and the first smaller inner diameter portion.
An outer diameter of the first large outer diameter portion in the second optical fiber is larger than an inner diameter of the second small inner diameter portion in the connection body, and the first large outer diameter in the second optical fiber. A step surface between the portion and the small outer diameter portion is in contact with the step surface between the first large inner diameter portion and the second small inner diameter portion in the connection body;
An outer diameter of the second large outer diameter portion in the first optical fiber is larger than an inner diameter of the first small inner diameter portion in the connection body, and the second large outer diameter in the first optical fiber. A step surface between the portion and the small outer diameter portion is in contact with a step surface between the second large inner diameter portion and the first small inner diameter portion in the connection body;
An outer diameter of the second large outer diameter portion in the second optical fiber is larger than an inner diameter of the second small inner diameter portion in the connection body, and the second large outer diameter in the second optical fiber. The step surface between a part and the said small outer diameter part is contacting with the step surface between the said 3rd large internal diameter part and the said 2nd small internal diameter part in the said connection body. Information processing device. Each of the first optical fiber and the second optical fiber has a core, a cladding layer formed on the periphery of the core, and a protective layer formed on the periphery of the cladding layer,
In the first optical fiber, the outer diameter of the core is substantially uniform, the thickness of the cladding layer is substantially uniform, and the thickness of the protective layer is the first large outer diameter portion. And the small outer diameter portion, the thickness of the protective layer is different between the second large outer diameter portion and the small outer diameter portion,
In the second optical fiber, the outer diameter of the core is substantially uniform, the thickness of the cladding layer is substantially uniform, and the thickness of the protective layer is the first large outer diameter. The information processing apparatus according to claim 6, wherein the information processing device is different between a diameter portion and the small outer diameter portion, and the thickness of the protective layer is different between the second large outer diameter portion and the small outer diameter portion.   The information processing apparatus according to claim 3, wherein the first optical fiber and the second optical fiber are in contact with each other with a predetermined pressure. A first fiber guide provided between the connector and the first optical signal converter in the first casing and having a curved through hole; and in the second casing. A second fiber guide provided between the connection body and the second optical signal converter and having a curved through hole;
The first optical fiber passes through the through hole of the first fiber guide, and the first fiber guide is fixed to the first optical fiber;
The information processing apparatus according to claim 1, wherein the second optical fiber passes through the through hole of the second fiber guide, and the second fiber guide is fixed to the second optical fiber. .   The information processing apparatus according to claim 10, wherein each of the first fiber guide and the second fiber guide has a curved cylindrical shape having a crack. The first fiber guide is fixed to the first housing;
The information processing apparatus according to claim 9 or 10, wherein the second fiber guide is fixed to the second casing. An optical signal transmission medium for transmitting an optical signal,
The signal transmission medium includes a connection body having a through hole, a first optical fiber having one end inserted into the through hole of the connection body, and one end inserted into the through hole of the connection body. A second optical fiber in contact with the first optical fiber,
An optical signal transmission medium, wherein the connection body rotatably connects the first optical fiber and the second optical fiber.

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