JP4133771B2 - Optical transmission system and optical transmission unit - Google Patents

Description

  The present invention relates to an optical transmission system in which a new communication line is inserted into an existing optical transmission system using optical fibers.

  Conventionally, in a communication system such as a security sensor that does not frequently transmit and receive data, an ISDN (Integrated Services Digital Network) that can simultaneously use a plurality of communication lines is often used (for example, Patent Document 1). reference.). ISDN is a digital communication network that performs data communication through a normal telephone line. For example, the ISDN is logically composed of three communication lines. It has one D channel with a communication speed of 16 kbps used for control and two B channels with 64 kbps used for communication. Since two communication lines can be used simultaneously, it is possible to connect to the network while using the telephone.

  However, ISDN must newly install a terminal adapter when the system is introduced, and there is a case where an enormous cost is required for the introduction of the ISDN communication system such as the installation cost of the terminal adapter.

In addition, along with FTTH (Fiber To The Home), which promotes the spread of optical transmission systems using optical fibers in recent years, when optical transmission systems become widespread, the above-mentioned security sensors and the like are frequently added to existing optical transmission systems. Therefore, it is necessary to insert and use a communication line that does not transmit / receive data.
JP 2000-165552 A

  Therefore, the present invention provides an optical transmission unit that can be used by inserting a new information transmission device such as the above-described security sensor without a significant design change in the configuration of an existing optical transmission system. Objective. It is another object of the present invention to provide an optical transmission system using this optical transmission unit.

  In order to solve the above problems, the present invention provides an optical transmission unit in an existing optical transmission system configured by a first optical transmission device and a second optical transmission device that perform point-to-point transmission in a physical layer. An optical transmission system configured by inserting the optical transmission unit and the optical transmission unit. Each optical transmission unit includes at least an optical transmission device that performs point-to-point transmission in the physical layer with the first optical transmission device. In an optical transmission system configured by inserting an optical transmission unit, An optical signal transmitted between the first optical transmission apparatus and the second optical transmission apparatus is transmitted without significant design change in the configuration of the optical transmission system, or a new one is added to the first optical transmission apparatus. It is characterized in that it is possible to select an optical transmission device to be used by controlling whether a new communication line is established with the inserted optical transmission device. Further, another new optical transmission device capable of performing point-to-point transmission in the physical layer with the second optical transmission device is added between the first optical transmission device and the second optical transmission device. Inserted and transmitted to the optical signal output from the second optical transmission device to the first optical transmission device and to the optical signal output from the newly inserted optical transmission device to the first optical transmission device You can also set the ranking.

  Specifically, the optical transmission system according to the present invention includes a first optical transmission apparatus that performs point-to-point transmission in the physical layer and a point-to-point in the physical layer between the first optical transmission apparatus. -M (m is a natural number) connected in cascade between a second optical transmission device that performs point transmission and the first optical transmission device and the second optical transmission device. An optical transmission system comprising: an optical transmission unit, wherein the nth optical transmission unit (n is a natural number equal to or less than m) includes a point in the physical layer with the first optical transmission device. The (n + 2) -th optical transmission device that performs -to-point transmission, and an optical signal input to the n-th optical transmission unit from the first optical transmission device side toward the second optical transmission device And the (n + 2) th light transmission An n-th optical signal branching means for branching into two devices, an optical signal input to the n-th optical transmission unit from the second optical transmission device side, and an output from the (n + 2) -th optical transmission device An optical signal coupled to the first optical transmission device, and an optical signal is output from the (n + 2) optical transmission device to the first optical transmission device. N-th optical signal blocking means for blocking an optical signal input from the second optical transmission device side to the n-th optical transmission unit at a stage preceding the n-th optical signal coupling means, Is an optical transmission system.

  According to the above invention, a plurality of optical transmission units can be newly inserted and information transmission equipment can be connected to each optical transmission unit and used without significant design change in the configuration of the existing optical transmission system. It becomes possible.

  In the optical transmission system, the nth optical signal blocking means includes an nth optical switch that blocks or conducts an optical signal, and an nth control unit that controls the operation of the nth optical switch. The nth optical switch is inserted between the nth optical signal coupling means and the second optical transmission device, and the nth control unit is the (n + 2) th optical transmission device. It is desirable to control the operation of the nth optical switch to block the optical signal when it is detected that an optical signal is output toward the first optical transmission device.

  As described above, the above-described invention makes it possible to block an optical signal transmitted in an existing optical transmission system with a simple optical component, and to perform specific transmission control of an optical signal individually output from the inserted optical transmission unit. It provides a means.

  In addition, the optical transmission system according to the present invention includes a first optical transmission apparatus that performs point-to-point transmission in the physical layer and a point-to-point transmission in the physical layer between the first optical transmission apparatus. , And p (p is a natural number) optical transmission units connected in cascade between the first optical transmission device and the second optical transmission device. The q-th (q is a natural number less than or equal to p) optical transmission unit includes a point-to-to-point in the physical layer with the first optical transmission apparatus. a (2q + 2) th optical transmission apparatus capable of performing a point-to-point transmission in a physical layer between the (2q + 1) th optical transmission apparatus that performs point transmission, and the second optical transmission apparatus; Said An optical signal input to the q-th optical transmission unit from the side of the first optical transmission device is bifurcated to the second optical transmission device and to the (2q + 1) -th optical transmission device (2q− 1) an optical signal branching unit, and an optical signal input to the q-th optical transmission unit from the second optical transmission device side toward the first optical transmission device and the (2q + 2) -th optical signal A second q optical signal branching unit bifurcated into the optical transmission device; an optical signal branched toward the first optical transmission device by the second q optical signal branching unit; and the (2q + 1) th optical transmission device. A q-th optical signal coupling means for coupling the optical signal output from the second q optical signal branching means toward the first optical transmission apparatus on the first optical transmission apparatus side; Optical signal output from the optical transmission device toward the first optical transmission device Blocking in the qth optical transmission unit and blocking the optical signal output from the first optical transmission device to the second optical transmission device in the qth optical transmission unit, or An optical transmission system comprising: a q-th optical signal control unit that stops outputting an optical signal output from the (2q + 1) -th optical transmission device toward the first optical transmission device.

  According to the above invention, a plurality of optical transmission units can be newly inserted and information transmission equipment can be connected to each optical transmission unit and used without significant design change in the configuration of the existing optical transmission system. It becomes possible. In addition, since the optical transmission unit includes the fourth optical transmission device, optical signals transmitted in the existing optical transmission system and optical signals output individually from the plurality of optical transmission units inserted in the existing optical transmission system It is possible to set a transmission order for transmitting any one of the optical signals.

  In the optical transmission system, the q-th optical signal control means includes a (2q-1) th optical switch for blocking or conducting an optical signal, a second q optical switch for blocking or conducting an optical signal, and the first A (2q-1) optical switch, a second q optical switch, and a qth control unit that controls the operation of the (2q + 1) optical transmission apparatus, and the (2q-1) optical The switch is inserted between the 2q-th optical signal branching means and the q-th optical signal coupling means, and the secondq optical switch is connected to the (2q-1) th optical signal branching means and the first-th optical signal branching means. The q-th control unit detects that an optical signal is output from the (2q + 1) -th optical transmission device to the first optical transmission device. Sometimes the (2q-1) -th optical switch and the second-q optical switch That the (2q-1) optical switch and the 2q optical switch both block the optical signal, or that the (2q + 2) optical transmission device has received the optical signal. When detected, the operation of the (2q + 1) th optical transmission device is controlled to stop outputting the optical signal output from the (2q + 1) th optical transmission device toward the first optical transmission device. Is desirable.

  As described above, the above-described invention enables a simple optical component to block an optical signal transmitted in an existing optical transmission system and an optical signal output individually from an optical transmission unit inserted in the existing optical transmission system. The present invention provides specific transmission control means for optical signals transmitted in an optical transmission system.

  In addition, the optical transmission system according to the present invention includes a first optical transmission apparatus that performs point-to-point transmission in the physical layer and a point-to-point transmission in the physical layer between the first optical transmission apparatus. And s (s is a natural number) optical transmission units connected in cascade between the first optical transmission device and the second optical transmission device. The t-th (t is a natural number less than or equal to s) optical transmission unit includes a point-to-to-point in the physical layer with the first optical transmission apparatus. a (2t + 2) th optical transmission apparatus capable of performing a point-to-point transmission in the physical layer between the (2t + 1) th optical transmission apparatus that performs point transmission, and the second optical transmission apparatus; Said The optical signal input to the t-th optical transmission unit from the side of the first optical transmission device is bifurcated to the second optical transmission device and to the (2t + 1) -th optical transmission device (2t− 1) an optical signal branching unit, and an optical signal input to the t-th optical transmission unit from the second optical transmission device side toward the first optical transmission device and the (2t + 2) -th optical signal. A second t optical signal branching unit bifurcated into the optical transmission device; an optical signal branched toward the first optical transmission device by the second t optical signal branching unit; and the (2t + 1) optical transmission device. T-th optical signal coupling means for coupling the optical signal output from the second t-th optical signal branching means toward the first optical transmission apparatus on the first optical transmission apparatus side, and the second t Branching toward the first optical transmission device by the optical signal branching means. Either the optical signal output from the optical signal output from the (2t + 1) th optical transmission device or the optical signal output from the (2t + 1) th optical transmission device is blocked before the t-th optical signal coupling means, and the other optical signal is conducted. And an optical signal blocking means.

  According to the above invention, a plurality of optical transmission units can be newly inserted and information transmission equipment can be connected to each optical transmission unit and used without significant design change in the configuration of the existing optical transmission system. It becomes possible. In addition, since the optical transmission unit includes the fourth optical transmission device, optical signals transmitted in the existing optical transmission system and optical signals output individually from the plurality of optical transmission units inserted in the existing optical transmission system It is possible to set a transmission order for transmitting any one of the optical signals.

  In the optical transmission system, the t-th optical signal blocking means includes a (2t-1) optical switch that blocks or conducts an optical signal, a second t optical switch that blocks or conducts an optical signal, and the first optical switch. A (2t-1) optical switch and a t-th control unit for controlling the operation of the second t optical switch, wherein the (2t-1) optical switch is the t-th optical signal coupling means. And the second t optical signal branching means, and the second t optical switch is inserted between the t th optical signal coupling means and the (2t + 1) optical transmission device, The t-th control unit outputs an optical signal from the (2t + 1) optical transmission device to the first optical transmission device, or the (2t + 2) optical transmission device receives the optical signal. (2t-1) optical switch and To block light signal by either one of the optical switches and controls the operation of the optical switch of the first 2t, it is desirable to conduct the optical signal by the other optical switch.

  As described above, the above-described invention enables a simple optical component to block an optical signal transmitted in an existing optical transmission system and an optical signal output individually from an optical transmission unit inserted in the existing optical transmission system. The present invention provides specific transmission control means for optical signals transmitted in an optical transmission system.

The optical transmission unit according to the present invention includes an optical transmission device that performs point-to-point transmission in a physical layer with an opposite optical transmission device, and another optical transmission device that is opposite to the opposite optical transmission device. And an optical signal branching means for branching the optical signal output from the opposite optical transmission device to the opposite optical transmission device and to the optical transmission device, and the relative The optical signal output from the other optical transmission device and the optical signal output from the optical transmission device are disposed between the other optical transmission device and the opposite optical transmission device. An optical signal coupling means coupled toward the transmission device, and connected to the optical signal coupling means between the optical signal coupling means and the other optical transmission device opposed to the optical signal coupling device; Opposite light transmission An optical switch that blocks or conducts an optical signal output toward the device, and an operation of the optical switch when it is detected that the optical signal is output from the optical transmission device toward the opposite optical transmission device A control unit that controls the optical signal to block the optical signal.

  According to the above-described invention, it is possible to insert a desired number of information transmission devices without a significant design change in the configuration of an existing optical transmission system.

An optical transmission unit according to the present invention includes a first optical transmission device that performs point-to-point transmission in a physical layer with an opposite optical transmission device, and another optical device that is opposed to the opposite optical transmission device. A second optical transmission device disposed between the optical transmission device and capable of performing point-to-point transmission in the physical layer with the other optical transmission device; and the opposite optical transmission The first optical transmission device is arranged between the optical transmission device and the other optical transmission device opposed to each other, and the optical signal output from the opposite optical transmission device is directed to the other optical transmission device opposed to the first optical transmission device. The optical signal output from the other optical transmission device is arranged between the first optical signal branching means for branching into two and the opposing optical transmission device and the other optical transmission device. The second optical transmission device The second optical signal branching means bifurcated toward the opposite optical transmission device, and between the second optical signal branching means and the opposite optical transmission device, and Optical signal coupling means for coupling the optical signal branched toward the opposite optical transmission device by the optical signal branching means and the optical signal output from the first optical transmission device toward the opposite optical transmission device And blocking or conducting an optical signal inserted between the second optical signal branching unit and the optical signal coupling unit and output from the other optical transmission device to the opposite optical transmission device A first optical switch to be operated, and the first optical switch and the second optical switch when it is detected that an optical signal is output from the first optical transmission device to the opposite optical transmission device Controlling the operation of the first Both the switch and the second optical switch block the optical signal, or control the operation of the first optical transmission device when detecting that the second optical transmission device has received the optical signal, A control unit configured to stop outputting an optical signal output from the first optical transmission device toward the opposite optical transmission device.

  According to the above invention, it is possible to insert a desired number of information transmission devices without significant design change in the configuration of an existing optical transmission system, and an optical signal and insertion transmitted in the existing optical transmission system. It is possible to set a transmission order for transmitting any one of the optical signals individually output from the plurality of optical transmission units.

An optical transmission unit according to the present invention includes a first optical transmission device that performs point-to-point transmission in a physical layer with an opposite optical transmission device, and another optical device that is opposed to the opposite optical transmission device. A second optical transmission device disposed between the optical transmission device and capable of performing point-to-point transmission in the physical layer with the other optical transmission device; and the opposite optical transmission The first optical transmission device is arranged between the optical transmission device and the other optical transmission device opposed to each other, and the optical signal output from the opposite optical transmission device is directed to the other optical transmission device opposed to the first optical transmission device. The optical signal output from the other optical transmission device is arranged between the first optical signal branching means for branching into two and the opposing optical transmission device and the other optical transmission device. The second optical transmission device The second optical signal branching means bifurcated toward the opposite optical transmission device, and between the second optical signal branching means and the opposite optical transmission device, and Optical signal coupling means for coupling the optical signal branched toward the opposite optical transmission device by the optical signal branching means and the optical signal output from the first optical transmission device toward the opposite optical transmission device When,
A second optical signal inserted between the second optical signal branching unit and the optical signal coupling unit and configured to block or conduct an optical signal output from the other optical transmission device to the opposite optical transmission device; Or an optical switch inserted between the first optical transmission device and the first optical transmission device and the optical signal coupling means to block or output an optical signal output from the first optical transmission device toward the optical signal coupling means. Detecting that an optical signal is output from the first optical transmission device to the opposing optical transmission device or that the second optical transmission device has received the optical signal, and the second optical switch to be conducted A controller that controls the operation of the first optical switch and the second optical switch to block the optical signal by one of the optical switches and to conduct the optical signal by the other optical switch; Optical transmission unit comprising A.

  According to the above invention, it is possible to insert a desired number of information transmission devices without significant design change in the configuration of an existing optical transmission system, and an optical signal and insertion transmitted in the existing optical transmission system. It is possible to set a transmission order for transmitting any one of the optical signals individually output from the plurality of optical transmission units.

  The optical transmission system of the present invention can perform communication by inserting an information transmission device into an existing optical transmission system without a significant design change in the configuration of the existing optical transmission system. Further, it becomes possible to secure communication by preferentially selecting an optical signal of either an existing optical transmission system or a newly inserted information transmission device. In the optical transmission unit according to the present invention, a desired number of information transmission devices can be inserted and communicated without a significant design change in the configuration of an existing optical transmission system.

  Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings. However, the present invention is not construed as being limited to these descriptions.

(Embodiment 1)
FIG. 1 shows a schematic configuration diagram of an optical transmission system according to the present embodiment. The optical transmission system 10 includes a first optical transmission device 31 that performs point-to-point transmission in the physical layer and a second optical device that performs point-to-point transmission in the physical layer between the first optical transmission device 31. And the optical transmission unit 11 inserted into an existing optical transmission system constituted by the first optical transmission device 31 and the second optical transmission device 32.

  Further, the optical transmission unit 11 includes a third optical transmission device 33 that performs point-to-point transmission in the physical layer with the first optical transmission device 31, a first optical transmission device 31, and a second optical transmission device 31. The optical signal 71 arranged between the optical transmission device 32 and the optical signal 71 output from the first optical transmission device 31 is branched to the second optical transmission device 32 and to the third optical transmission device 33. The optical signal 75 output from the second optical transmission device 32 and the third optical transmission device 33 are arranged between the signal branching means 41, the second optical transmission device 32, and the first optical transmission device 31. The optical signal coupling means 42 for coupling the optical signal 73 output from the optical signal 73 toward the first optical transmission device 31, and the optical signal coupling means 42 between the optical signal coupling means 42 and the second optical transmission device 32, The second optical transmission device 32 to the first optical transmission device 31 are connected. An optical switch 52 as an optical signal blocking means for blocking or conducting an optical signal 75 which is output to a control unit 51 for controlling the operation of the optical switch 52, it is provided.

  The first optical transmission device 31, the second optical transmission device 32, and the third optical transmission device 33 are each connected to an information transmission device that transmits and receives information, and a signal output from the information transmission device is converted into an optical signal. It has a function of converting and outputting it to another opposing optical transmission device and a function of converting an optical signal output from another opposing optical transmission device into, for example, an electrical signal and outputting it to an information transmission device. In the present embodiment, an embodiment has been described in which an electrical signal and an optical signal are converted into each other with respect to the optical transmission device. However, transmission / reception of signals between the optical transmission device and the information transmission device is performed by optical fibers. You may perform by transmission / reception or transmission / reception by radio | wireless. By transmitting and receiving signals between the optical transmission device and the information transmission device by transmitting and receiving optical signals using optical fibers, it is possible to transmit and receive information at high speed, and the attenuation of optical signals is reduced to the attenuation of electrical signals. Since it is smaller than that, information can be transmitted and received over a long distance. On the other hand, by transmitting and receiving signals between the optical transmission device and the information transmission device wirelessly, for example, the arrangement of the information transmission device is not limited by the position of the optical transmission device, and the information transmission device can be freely arranged. And

  Between the optical transmission apparatuses, point-to-point transmission is performed in the physical layer. The optical transmission device may have a function of physically terminating all optical signals output from the opposite optical transmission devices and outputting them to the information transmission device connected to the optical transmission device as described above. The second optical transmission device 32 identifies the MAC (Media Access Control) address in the optical signal 74 output from the first optical transmission device 31 toward the second optical transmission device 32, and the optical signal 74. If it is not output to the second optical transmission device 32, the second optical transmission device 32 may have a function of discarding. With this function, it is possible to incorporate only information necessary for the information transmission equipment connected to each optical transmission device.

  The optical signal branching means 41 converts the optical signal 71 output from the first optical transmission device 31 into an optical signal 74 directed to the second optical transmission device 32 and an optical signal 72 directed to the third optical transmission device 33. Has a branching function. As the optical signal branching means 41, for example, a 2-input 2-output optical directional coupler can be applied.

  FIG. 4 shows a schematic configuration diagram of the optical directional coupler. In the optical directional coupler 100, when two optical waveguides 101 and 102 having the same shape are arranged adjacent to each other in parallel, the light 103 input to one optical waveguide 101 transfers energy to the other optical waveguide 102. It is an optical component that uses the phenomenon of propagating. That is, since the two lights 103 and 104 respectively input from one side are branched, the light 103 can be branched or the light 103 and the light 104 can be coupled.

  By using the optical directional coupler 100 shown in FIG. 4 for the optical signal branching means 41 shown in FIG. 1, the energy of the optical signal is not only split into two on a one-on-one basis, but also split into two at an arbitrary ratio. be able to. For example, 90% of the energy of the optical signal can be branched to the optical signal 74 directed to the second optical transmission device 32, and 10% can be branched to the optical signal 72 directed to the third optical transmission device 33. By changing the branching ratio of the optical signal energy, a decrease in the energy of the optical signal 74 output from the first optical transmission device 31 to the second optical transmission device 32 can be suppressed, and the first optical transmission is performed. The influence on the transmission of the optical signal to the existing optical transmission system configured by the device 31 and the second optical transmission device 32 can be reduced. The attenuation of the optical signal energy due to the branching can be avoided by an optical amplifier that amplifies the optical signal. For example, by inserting an optical amplifier between the optical signal branching means 41 and the third optical transmission device 33, the optical signal 72 is amplified even when the optical signal 72 has 10% energy of the optical signal 71. Thus, the third optical transmission apparatus can receive the signal.

  The optical signal coupling means 42 has a function of coupling the optical signal 73 output from the third optical transmission device 33 and the optical signal 75 output from the second optical transmission device 32 toward the first optical transmission device 31. Have As the optical signal coupling means 42, for example, the optical directional coupler 100 shown in FIG.

  By applying the optical directional coupler 100 shown in FIG. 4 to the optical signal branching unit 41 and the optical signal coupling unit 42, the existing light configured by the first optical transmission device 31 and the second optical transmission device 32 is used. When the third optical transmission device 33 is inserted into the transmission system, the optical fiber connecting the first optical transmission device 31 and the second optical transmission device 32 is cut, and the cut ends are optically connected. It is only necessary to connect to the directional coupler, and the insertion of the third optical transmission device 33 is easy.

In the present embodiment, an embodiment in which an existing optical transmission system constituted by the first optical transmission device 31 and the second optical transmission device 32 is constituted by a two-core optical fiber is shown. The existing optical transmission system configured by the first optical transmission device 31 and the second optical transmission device 32 may be configured by a single-core optical fiber. In this case, the optical signal branching unit and the optical signal coupling unit inserted in the existing optical transmission system are realized by using, for example, a combination of the optical directional coupler 100 shown in FIG. 4 and a WDM (Wavelength Division Multiplexing) filter. can do. The WDM filter is an optical component having a function of branching and coupling for each wavelength of an optical signal. For example, when two optical signals having wavelengths λ ₁ and λ ₂ are input to a WDM filter having one input and two outputs, λ ₁ One optical signal and one optical signal of λ ₂ are output. The 1-input 2-output also becomes 2-input 1-output, and the optical signals of wavelengths λ ₁ and λ ₂ inputted one by one are combined and outputted.

FIG. 5 shows a schematic configuration diagram of an optical signal branching unit and an optical signal coupling unit configured by applying a WDM filter. As shown in FIG. 5, an optical signal 501 is transmitted between WDM filters 201, 202, and 203 connected to the first optical transmission device 31, the second optical transmission device 32, and the third optical transmission device 33, respectively. An optical directional coupler 301 that branches to an optical signal 503 that is directed to the third optical transmission device 33 and an optical directional coupler 302 that couples the optical signal 504 toward the first optical transmission device 31 are connected. ing. The first optical transmission device 31 and the second optical transmission device 32 are connected to the WDM filters 201 and 202 by one-core optical fibers 401 and 402, respectively. The optical signal 501 and the optical signal 502 are point-to-to- Point transmission can be performed. Here, for example, the wavelength of the optical signal 501 is λ ₁ , and the wavelength of the optical signal 502 is λ ₂ . By connecting the optical directional coupler and the WDM filter as described above, the third optical transmission device 33 is added to the existing optical transmission system configured by the first optical transmission device 31 and the second optical transmission device 32. For example, the optical signal 501 having the wavelength λ ₁ output from the first optical transmission device 31 may be branched into the optical signal 503 having the wavelength λ ₁ output toward the third optical signal. In addition, the optical signal 504 having the wavelength λ ₂ output from the third optical transmission device 33 can be combined with the optical signal 502 output toward the first optical transmission device 31.

  The optical switch 52 shown in FIG. 1 can be realized by having a function of mechanically blocking or conducting an optical signal 75 output from the second optical transmission device 32 toward the first optical transmission device 31. For example, when the ends of two cut optical fibers face each other and the axes of the optical fibers coincide with each other, the optical signal 75 is conducted, and when the axes are shifted, the optical signal 75 is blocked. This mechanism can be realized by moving a base having a V-groove supporting the optical fiber by a piezoelectric actuator in a direction perpendicular to the axis of the optical fiber. The piezoelectric actuator is an actuator that uses a piezoelectric element that expands in the direction when a current flows, and the amount of elongation can be controlled by the voltage applied to the piezoelectric actuator. If this optical switch 52 is used as an optical signal blocking means, the blocking or conduction of the optical signal 75 can be easily controlled by a voltage signal output from the control unit 51 described later.

  As the optical switch, a planar lightwave circuit using an electro-optic effect or a thermo-optic effect may be used. The electro-optic effect is an effect that the refractive index of a material changes when an electric field is applied. Examples of the material having this effect include materials such as lithium niobate. The planar lightwave circuit is an optical circuit in which an optical waveguide is formed on a substrate. A planar lightwave circuit using a material having an electro-optic effect is inserted into an optical fiber so that an optical signal is transmitted through the planar lightwave circuit.

In order to block the transmitted optical signal, an electric field may be applied to the planar lightwave circuit. By applying an electric field to the planar lightwave circuit, the refractive index in the planar lightwave circuit changes due to the electro-optic effect. When the refractive index changes, the transmission path of the optical signal changes, and the optical signal can be blocked by shifting the optical signal from the original output position. If the optical switch 52 using this principle is used as the optical signal blocking means, the optical signal 75 is blocked or turned on by an optical switch using a piezoelectric actuator by a voltage signal output from the control unit 51 described later. Similarly, it can be easily controlled. Moreover, you may utilize the thermo-optic effect in which the refractive index of material changes by applying a heat instead of an electric field. An example of a material having a thermo-optic effect is SiO ₂ . Such a planar lightwave circuit can also be applied to other optical switches.

  The control unit 51 controls the operation of the optical switch 52. For example, the function of controlling the operation of the optical switch 52 as described above by a voltage signal, and the optical signal 73 is output from the third optical transmission device 33. It has a function to detect that. In the optical transmission system 10, when the control unit 51 detects that the optical signal 73 is output from the third optical transmission device 33 to the first optical transmission device 31, the operation of the optical switch 52 is controlled. It is desirable to block the optical signal 75. By detecting that the optical signal 73 is output from the third optical transmission device 33 toward the first optical transmission device 31 by the control unit 51, the optical signal 75 is forcibly blocked by the optical switch 52, The output of the optical signal 73 from the third optical transmission device 33 toward the first optical transmission device 31 is based on the output of the optical signal 75 from the second optical transmission device 32 toward the first optical transmission device 31. It becomes possible to give priority. Therefore, in the optical transmission system 10, there is no need to perform control for synchronizing and outputting the optical signal 73 and the optical signal 75 output from the second optical transmission device 32 and the third optical transmission device 33. The third optical transmission device 33 can be easily inserted and used in an existing optical transmission system composed of the optical transmission device 31 and the second optical transmission device 32.

  Note that m (m is a natural number) light between the first optical transmission device 31 as the opposite optical transmission device and the second optical transmission device 32 as the opposite optical transmission device. Transmission units 11 can be connected in cascade. By connecting the optical transmission units 11 in cascade, a desired number of information transmission devices can be inserted into an existing optical transmission system composed of the first optical transmission device 31 and the second optical transmission device 32. . Here, in the n-th optical transmission unit (n is a natural number equal to or less than m), the (n + 2) -th optical transmission device corresponds to the third optical transmission device 33 shown in FIG. The nth optical signal branching means corresponds to the optical signal branching means 41 shown in FIG. The nth optical signal coupling means corresponds to the optical signal coupling means 42 shown in FIG. The nth optical switch corresponds to the optical switch 52 shown in FIG. 1 and has a function of blocking or conducting an optical signal input to the nth optical transmission unit from the second optical transmission device 32 side.

  In this case, the transmission order of the optical signals output from the (n + 2) th optical transmission device of the nth optical transmission unit toward the first optical transmission device 31 is higher on the side closer to the first optical transmission device 31. Therefore, when an information transmission device is connected to the nth optical transmission unit, it is desirable to connect a device having a higher transmission order to the first optical transmission device 31 side.

  Here, an example of the operation of the optical transmission system 10 will be described with reference to FIG. First, the optical signal 71 output from the first optical transmission device 31 is an optical signal 74 directed to the second optical transmission device 32 by the optical signal branching means 41, and an optical signal 72 directed to the third optical transmission device 33. , Two branches. The second optical transmission device 32 and the third optical transmission device 33 take an optical signal into the optical transmission device, convert it into an electrical signal, and output it to an information transmission device. As described above, transmission / reception of signals between the optical transmission apparatus and the information transmission device may be performed by transmission / reception of optical signals using optical fibers or transmission / reception of radio waves by radio. As described above, if the optical signal 71 is not an optical signal output to each optical transmission device, each optical transmission device may identify and discard the received optical signal. Hereinafter, the optical transmission apparatus will be described as an embodiment in which a received optical signal is identified, and the received optical signal is converted into an electrical signal and output to an information transmission device.

  For example, when the optical signal 71 is a transmission request signal to the third optical transmission device 33, the transmission request signal is discarded by the second optical transmission device 32, and is converted into an electric signal 77 by the third optical transmission device 33. It is converted and output to the information transmission device 36. The information transmission device 36 that has received the electrical signal 77 responds to the transmission request and outputs an electrical signal 78 as a response signal toward the third optical transmission device 33. The third optical transmission device 33 that has received the electrical signal 78 converts the electrical signal 78 into an optical signal 73 and outputs it to the first optical transmission device 31.

  At this time, for example, in the process of converting the electrical signal 78 into the optical signal 73, a part of the electrical signal 78 is output to the control unit 51 as the optical signal output detection signal 61. The control unit 51 that has detected the optical signal output detection signal 61 outputs a voltage signal as the optical switch control signal 62 to the optical switch 52 and outputs the voltage signal from the second optical transmission device 32 toward the first optical transmission device 31. The optical signal 75 is forcibly cut off.

  The optical signal 73 output from the third optical transmission device 33 is coupled toward the first optical transmission device 31 by the optical signal coupling means 42. Since the optical signal 75 output from the second optical transmission device 32 toward the first optical transmission device 31 is blocked by the optical switch 52, the optical signal 73 and the optical signal 75 may collide. Absent.

  On the other hand, when the optical signal 71 is an information signal to the second optical transmission device 32, the optical signal 72 is discarded in the third optical transmission device 33 and converted into an electric signal 76 in the second optical transmission device 32. And output to the information transmission device 35 connected to the second optical transmission device 32.

  Further, when the control unit 51 does not detect the optical signal output detection signal 61, the optical signal 75 is made conductive by the optical switch 52. Therefore, the optical signal 75 output from the second optical transmission device 32 is the first as it is. Are output toward the optical transmission device 31.

  In the optical transmission system 10 that performs the above operation, the information transmission device 36 connected to the third optical transmission device 33 includes, for example, a camera using a CCD sensor, a sensor that detects opening and closing of a window, and a room temperature. Information transmission equipment that does not send and receive information frequently, such as temperature sensors, security sensors such as smoke sensors that detect smoke generated indoors, and meter reading meters that measure the amount of gas, water and electricity used. It is desirable to be. These information transmission devices have a smaller number of output times of information than information terminals such as computers, and the existing optical transmission system composed of the first optical transmission device 31 and the second optical transmission device 32. This is because the traffic is not affected so much and it is not necessary to use a special control means regarding the output of the optical signal. Further, for example, the optical transmission system 10 can perform an operation that takes time to transmit an optical signal, such as operating a CCD camera installed indoors according to an instruction from the outside.

  When the information transmission device 35 connected to the second optical transmission device 32 does not transmit or receive information, even if the second optical transmission device 32 is exclusively used for optical signal transmission to the outside, the existing optical transmission system is affected. If not, the optical transmission system 10 can be used effectively.

(Embodiment 2)
FIG. 2 shows a schematic configuration diagram of the optical transmission system according to the present embodiment. The optical transmission system 20 includes a first optical transmission device 31 that performs point-to-point transmission in the physical layer and a second optical device that performs point-to-point transmission in the physical layer between the first optical transmission device 31. And an optical transmission unit 21 inserted into an existing optical transmission system constituted by the first optical transmission device 31 and the second optical transmission device 32.

  The optical transmission unit 21 includes a third optical transmission device 33 that performs point-to-point transmission in the physical layer with the first optical transmission device 31, and a second optical transmission device 32. The first optical transmission device 34 capable of performing point-to-point transmission in the physical layer, and the first optical transmission device 31 and the second optical transmission device 32, and A first optical signal branching unit 43 for branching the optical signal 81 output from the optical transmission device 31 toward the second optical transmission device 32 and the third optical transmission device 33; and a second optical transmission device 32 and the first optical transmission device 31, the optical signal 86 output from the second optical transmission device 32 and the optical signal 83 output from the third optical transmission device 33 are used as the first optical signal. First optical signal coupling means coupled toward the transmission device 31 4 and an optical signal 86 that is disposed between the first optical transmission device 31 and the second optical transmission device 32 and that is output from the second optical transmission device 32 toward the first optical transmission device 31. A second optical signal branching unit 45 that branches into the first optical transmission device 31 and a fourth optical transmission device 34; a first optical signal coupling unit 44; and a second optical signal branching unit 45; A first optical switch 54 serving as an optical signal control means for blocking or conducting an optical signal 86 inserted between the second optical transmission device 32 and output from the second optical transmission device 32 to the first optical transmission device 31; The optical signal 81 that is inserted between the first optical signal branching means 43 and the second optical transmission device 32 and is output from the first optical transmission device 31 toward the second optical transmission device 32 is cut off or conducted. A second optical switch 55 as an optical signal control means, a first optical switch 54 and A control unit 53 for controlling the second operation of the optical switch 55, are provided. In addition to this, the second light that couples the optical signal 85 output from the fourth optical transmission device 34 and the optical signal 81 output from the first optical transmission device 31 toward the second optical transmission device 32. The signal coupling unit 46 may be provided between the optical switch 55 and the second optical transmission device 32.

  In the optical transmission system 20, the first, second, third and fourth optical transmission devices, first and second optical signal branching means, first and second optical signal coupling means, first and second Since the optical switches are the same as those described in the first embodiment, description thereof will be omitted.

  The control unit 53 controls the operation of the first optical switch 54, the second optical switch 55, and the third optical transmission device 33. For example, as described above, the control unit 53 includes an optical switch including a piezoelectric actuator. The function controlled by the voltage signal, the output of the optical signal 83 from the third optical transmission device 33, and the reception of the optical signal 84 output from the second optical transmission device 32 by the fourth optical transmission device 34 It has a function to detect. When it is detected that the optical signal 83 is output from the third optical transmission device 33 toward the first optical transmission device 31, the operations of the first optical switch 54 and the second optical switch 55 are controlled. The first optical switch 54 and the second optical switch 55 both block the optical signal, or the third optical transmission device 33 when the fourth optical transmission device 34 detects that the optical signal 84 has been received. It is desirable to stop the output of the optical signal 83 output from the third optical transmission device 33 toward the first optical transmission device 31 by controlling the above-described operation. The control unit 53 controls the operations of the first optical switch 54, the second optical switch 55, and the third optical transmission device 33, and outputs the optical signal 83 and the second optical signal output from the third optical transmission device 33. By forcibly selecting and outputting one of the optical signals 86 output from the transmission device 32, the optical signals output from the second optical transmission device 32 and the third optical transmission device 33 are synchronized. There is no need to perform output control, and the third optical transmission device 33 can be easily inserted and used in an existing optical transmission system constituted by the first optical transmission device 31 and the second optical transmission device 32. Can do.

  Further, since the optical signal 86 output from the second optical transmission device 32 is received by the fourth optical transmission device 34 before being blocked by the first optical switch 54, the third optical transmission is performed. The transmission order of the optical signal 83 output from the device 33 toward the first optical transmission device 31 and the optical signal 86 output from the second optical transmission device 32 toward the first optical transmission device 31 are set. You can also. For example, when the fourth optical transmission device 34 receives the optical signal 84, the optical signals 81 and 86 are turned on by the first optical switch 54 and the second optical switch 55, and are transmitted to the third optical transmission device 33. The output of the optical signal 83 is stopped. When the control unit 53 operates as described above, the transmission order of the optical signal 86 output from the second optical transmission device 32 to the first optical transmission device 31 is changed from the third optical transmission device 33 to the first. The transmission order of the optical signal 83 output toward the optical transmission device 31 can be made higher. The transmission order can be defined by, for example, the operation setting of the control unit 53.

  In addition, p (p is a natural number) light between the 1st optical transmission apparatus 31 as an opposing optical transmission apparatus, and the 2nd optical transmission apparatus 32 as another optical transmission apparatus facing. Transmission units 21 can be connected in cascade. A desired number of information transmission devices can be inserted into an existing optical transmission system by connecting the optical transmission units 21 in cascade. Here, in the q-th optical transmission unit (q is a natural number equal to or less than p), the (2q + 1) -th optical transmission device corresponds to the third optical transmission device 33 shown in FIG. The (2q + 2) th optical transmission apparatus corresponds to the fourth optical transmission apparatus 34 shown in FIG. The (2q-1) th optical signal branching means corresponds to the first optical signal branching means 43 shown in FIG. The second q optical signal branching means corresponds to the second optical signal branching means 45 shown in FIG. The q-th optical signal coupling means corresponds to the first optical signal coupling means 44 shown in FIG. The (2q-1) th optical switch corresponds to the first optical switch 54 shown in FIG. 2, and blocks the optical signal input to the qth optical transmission unit from the second optical transmission device 32 side. Or, it has a function of conducting. The second q optical switch corresponds to the second optical switch 55 shown in FIG. 2, and has a function of blocking or conducting an optical signal input to the q th optical transmission unit from the first optical transmission device 31 side. Have When the optical transmission unit is used, the (2q + 1) th optical transmission device corresponds to the first optical transmission device that performs point-to-point transmission with the opposite optical transmission device, and the (2q + 2) th optical transmission device. The transmission apparatus corresponds to a second optical transmission apparatus capable of performing point-to-point transmission with another opposing optical transmission apparatus.

  In this case, in the present embodiment, an optical signal input from the second optical transmission device 32 side to the qth optical transmission unit is blocked in the qth optical transmission unit, or (2q + 1) th optical signal is transmitted. Since either one of the optical signals output from the transmission device can be freely output to the first optical transmission device 31, it is possible to select between the first optical transmission device 31 and the second optical transmission device 32. The optical signal output from the (2q + 1) th optical transmission device of any qth optical transmission unit connected in cascade can be output toward the first optical transmission device 31. Since the optical signal output from the (2q + 1) th optical transmission device of an arbitrary qth optical transmission unit can be output toward the first optical transmission device 31, the (2q + 1) th (2q + 1) th optical signal is output at the connection stage. Even if the transmission order of the information transmission devices connected to the optical transmission device is not determined, it is only necessary to freely change the internal settings of the optical transmission unit 21 during use, and the information transmission devices are not reconnected.

  Here, an example of the operation of the optical transmission system 20 will be described with reference to FIG. First, the optical signal 81 output from the first optical transmission device 31 is transmitted to the second optical transmission device 32 by the first optical signal branching unit 43 and the light toward the third optical transmission device 33. The signal 82 is branched into two. If the second optical transmission device 32 and the third optical transmission device 33 are optical signals output to the respective optical transmission devices, the optical signals are taken into the optical transmission devices and converted into electrical signals for information transmission. If it is output to a device and not an optical signal output to each optical transmission device, it is discarded.

  For example, when the optical signal 81 is a transmission request signal to the second optical transmission device 32, the optical signal 82 is discarded in the third optical transmission device 33, and the optical signal 81 in the second optical transmission device 32 is It is converted into an electric signal 80 and output to the information transmission device 37 connected to the second optical transmission device 32.

  The information transmission device 37 that has received the electrical signal 80 responds to the transmission request and outputs an electrical signal 79 as a response signal toward the second optical transmission device 32. The second optical transmission device 32 that has received the electrical signal 79 converts the electrical signal 79 into an optical signal 86 and outputs it to the first optical transmission device 31. A part of the optical signal 86 is branched by the second optical signal branching means 45 into an optical signal 84 output toward the fourth optical transmission device 34. The branched optical signal 84 is received by the fourth optical transmission device 34.

  At this time, for example, the fourth optical transmission device 34 converts the optical signal 84 into an electric signal, and outputs a part of the converted electric signal to the control unit 53 as the second optical signal output detection signal 93. The control unit 53 that has detected the second optical signal output detection signal 93 outputs a voltage signal as the optical transmission device control signal 95 to the third optical transmission device 33, and the third optical transmission device 33 receives the optical signal 83. Is forcibly stopped.

  The optical signal 86 output from the second optical transmission device 32 is coupled toward the first optical transmission device 31 by the first optical signal coupling means 44. Since the optical signal 83 output from the third optical transmission device 33 to the first optical transmission device 31 is stopped by the third optical transmission device 33, the optical signal 83, the optical signal 86, Will not collide.

  In the above operation example, the transmission order of the optical signals 83 output from the third optical transmission device 33 to the first optical transmission device 31 is determined from the second optical transmission device 32 to the first optical transmission device 31. Is lower than the transmission order of the optical signal 86 output toward the, but the transmission order can be reversed. For example, transmission control may be performed as follows.

  When the optical signal 81 is a transmission request signal to the third optical transmission device 33, the optical signal 81 is discarded in the second optical transmission device 32, and the optical signal 82 is an electric signal in the third optical transmission device 33. 87 is output to the information transmission device 38 connected to the third optical transmission device 33.

  The information transmission device 38 that has received the electrical signal 87 responds to the transmission request and outputs an electrical signal 88 as a response signal toward the third optical transmission device 33. The third optical transmission device 33 that has received the electrical signal 88 converts the electrical signal 88 into an optical signal 83 and outputs it to the first optical transmission device 31.

  At this time, for example, the third optical transmission device 33 outputs a part of the electric signal 88 to the control unit 53 as the first optical signal output detection signal 91. The control unit 53 that has detected the first optical signal output detection signal 91 sends a voltage signal as the first optical switch control signal 92 to the first optical switch 54 and a voltage signal as the second optical switch control signal 94. Are respectively output to the second optical switch 55, and the first optical switch 54 and the second optical switch 55 forcibly block the optical signals 81 and 86. Here, when the optical signal 86 is interrupted during transmission, the optical signal 81 as a retransmission request signal may be output from the first optical transmission device 31 toward the second optical transmission device 32. In this case, if the optical signal 81 is not blocked, the second optical transmission device 32 that has received the retransmission request signal retransmits the optical signal 86 many times. Therefore, the above problem can be avoided by blocking the optical signal 81 together with the optical signal 86.

  The optical signal 83 output from the third optical transmission device 33 is coupled toward the first optical transmission device 31 by the first optical signal coupling means 44. Since the optical signal 86 output from the second optical transmission device 32 toward the first optical transmission device 31 is blocked by the first optical switch 54, the optical signal 83 and the optical signal 86 collide with each other. There is nothing to do. Further, by providing the second optical signal coupling means 46, when the optical signal 83 is output from the third optical transmission device 33 toward the first optical transmission device 31, the fourth optical transmission device. The second optical transmission device 32 is output until the third optical transmission device 33 finishes outputting the optical signal 83 by outputting the optical signal 85 as an output stop signal from the 34 toward the second optical transmission device 32. It is also possible to stop the output of the optical signal 86.

  In the optical transmission system 20 that performs the above operation, the information transmission device 38 connected to the third optical transmission device 33 is, for example, a camera using a CCD sensor, a sensor that detects opening and closing of a window, and a room temperature. Information transmission equipment that does not send and receive information frequently, such as temperature sensors, security sensors such as smoke sensors that detect smoke generated indoors, and meter reading meters that measure the amount of gas, water, and electricity used. It is desirable to be. These information transmission devices have a smaller number of times of information output than information terminals such as computers, and the traffic of the existing optical transmission system configured by the first optical transmission device 31 and the second optical transmission device 32 is reduced. This is because it does not give much influence and it is not necessary to use a special control means relating to the output of the optical signal.

  In addition, the transmission order of information can be set for each security sensor and meter-reading meter. For example, since the information output from the meter-reading meter is not urgent, the transmission order is set low. On the other hand, since the information output from the smoke sensor is urgent, such as fire detection information, the transmission order is set higher than the transmission order of information output from any information transmission device. As described above, the optical transmission system 20 can freely set information transmission order.

  Further, for example, the optical transmission system 20 can perform an operation that takes time to transmit an optical signal, such as operating a CCD camera installed indoors according to an instruction from the outside.

(Embodiment 3)
FIG. 3 shows a schematic configuration diagram of the optical transmission system according to the present embodiment. The optical transmission system 23 performs the point-to-point transmission in the physical layer between the first optical transmission device 31 that performs point-to-point transmission in the physical layer and the first optical transmission device 31. And an optical transmission unit 24 inserted into an existing optical transmission system constituted by the first optical transmission device 31 and the second optical transmission device 32.

  Further, the optical transmission unit 24 includes a third optical transmission device 33 that performs point-to-point transmission in the physical layer with the first optical transmission device 31, and a second optical transmission device 32. The first optical transmission device 34 capable of performing point-to-point transmission in the physical layer, and the first optical transmission device 31 and the second optical transmission device 32, and A first optical signal branching unit 43 for branching the optical signal 81 output from the optical transmission device 31 toward the second optical transmission device 32 and the third optical transmission device 33; and a second optical transmission device 32 and the first optical transmission device 31, the optical signal 86 output from the second optical transmission device 32 and the optical signal 83 output from the third optical transmission device 33 are used as the first optical signal. First optical signal coupling means coupled toward the transmission device 31 4 and an optical signal 86 that is disposed between the first optical transmission device 31 and the second optical transmission device 32 and that is output from the second optical transmission device 32 toward the first optical transmission device 31. A second optical signal branching unit 45 that branches into the first optical transmission device 31 and a fourth optical transmission device 34; a first optical signal coupling unit 44; and a second optical signal branching unit 45; A first optical switch 54 serving as an optical signal blocking means for blocking or conducting an optical signal 86 inserted between the second optical transmission device 32 and output from the second optical transmission device 32 toward the first optical transmission device 31; The optical signal 83 inserted between the first optical signal coupling means 44 and the third optical transmission device 33 and output from the third optical transmission device 33 toward the first optical transmission device 31 is cut off or conducted. A second optical switch 55 as an optical signal blocking means, a first optical switch 54 and A control unit 56 for controlling the second operation of the optical switch 55, are provided. In addition to this, the second light that couples the optical signal 85 output from the fourth optical transmission device 34 and the optical signal 81 output from the first optical transmission device 31 toward the second optical transmission device 32. The signal coupling unit 46 may be provided between the first optical signal branching unit 43 and the second second optical transmission device 32.

  In the optical transmission system 23, the first, second, third and fourth optical transmission devices, first and second optical signal branching means, first and second optical signal coupling means, first and second Since the optical switches are the same as those described in the first embodiment, description thereof will be omitted.

  The control unit 56 controls the operation of the first optical switch 54 and the second optical switch 55. For example, as described above, the function of controlling the optical switch including the piezoelectric actuator by a voltage signal; It has a function of detecting that the optical signal 83 is output from the third optical transmission device 33 and that the fourth optical transmission device 34 has received the optical signal 84 output from the second optical transmission device 32. The first optical signal 83 is detected when the optical signal 83 is output from the third optical transmission device 33 toward the first optical transmission device 31 or when the fourth optical transmission device 34 receives the optical signal 84. It is desirable to control the operation of the optical switch 54 and the second optical switch 55 to block the optical signal 86 or the optical signal 83 by any one of the optical switches. The control unit 56 forcibly blocks the optical signal 86 or the optical signal 83 by any one of the first optical switch 54 and the second optical switch 55, whereby the third optical transmission device 33 or the second optical switch 33 It becomes possible to output the optical signal 86 or the optical signal 83 output from the optical transmission device 32 toward the first optical transmission device 31. That is, it is not necessary to perform control to output the optical signals output from the second optical transmission device 32 and the third optical transmission device 33 in synchronization with each other, and the first optical transmission device 31 and the second optical transmission device. The third optical transmission device 33 can be easily inserted and used in the existing optical transmission system constituted by 32.

  Further, since the optical signal 86 output from the second optical transmission device 32 is received by the fourth optical transmission device 34 before being blocked by the first optical switch 54, the third optical transmission is performed. The transmission order of the optical signal 83 output from the device 33 toward the first optical transmission device 31 and the optical signal 86 output from the second optical transmission device 32 toward the first optical transmission device 31 are set. You can also. For example, when the fourth optical transmission device 34 receives the optical signal 84, the optical signal 83 is blocked by the second optical switch 55 and the optical signal 86 is made conductive by the first optical switch 54. The transmission order of the optical signals 86 output from the optical transmission device 32 toward the first optical transmission device 31 is determined according to the transmission order of the optical signals 83 output from the third optical transmission device 33 toward the first optical transmission device 31. It can be higher than the transmission order. The transmission order can be defined by, for example, the operation setting of the control unit 56.

  Note that s (s is a natural number) light between the first optical transmission device 31 as the opposite optical transmission device and the second optical transmission device 32 as the other optical transmission device opposite to each other. Transmission units 24 can be connected in cascade. A desired number of information transmission devices can be inserted into an existing optical transmission system by connecting the optical transmission units 24 in cascade. Here, in the t-th optical transmission unit (t is a natural number equal to or less than s), the (2t + 1) -th optical transmission device corresponds to the third optical transmission device 33 shown in FIG. The (2t + 2) th optical transmission apparatus corresponds to the fourth optical transmission apparatus 34 shown in FIG. The (2t-1) th optical signal branching means corresponds to the first optical signal branching means 43 shown in FIG. The second t optical signal branching means corresponds to the second optical signal branching means 45 shown in FIG. The t-th optical signal coupling means corresponds to the first optical signal coupling means 44 shown in FIG. The (2t-1) th optical switch corresponds to the first optical switch 54 shown in FIG. 3, and blocks the optical signal input to the qth optical transmission unit from the second optical transmission device 32 side. Or, it has a function of conducting. The second t optical switch corresponds to the second optical switch 55 shown in FIG. 3, and blocks or conducts an optical signal output from the third optical transmission device 33 toward the first optical transmission device 31. It has a function. When the optical transmission unit is used, the (2t + 1) th optical transmission device corresponds to the first optical transmission device that performs point-to-point transmission with the opposite optical transmission device, and the (2t + 2) th optical transmission device. The transmission apparatus corresponds to a second optical transmission apparatus capable of performing point-to-point transmission with another opposing optical transmission apparatus.

  In this case, in the present embodiment, the operation of any one of the (2t-1) th optical switch and the second tth optical switch can be freely controlled in the tth optical transmission unit. The optical signal output from the (2t + 1) th optical transmission device of an arbitrary tth optical transmission unit connected in cascade between the optical transmission device 31 and the second optical transmission device 32 is the first optical signal. It can be output toward the optical transmission device 31. Since the optical signal output from the (2t + 1) th optical transmission device of an arbitrary t-th optical transmission unit can be output toward the first optical transmission device 31, the (2t + 1) th optical signal is output at the connection stage. Even if the transmission order of the information transmission devices connected to the optical transmission apparatus is not determined, it is only necessary to freely change the internal settings of the optical transmission unit 24 during use, and the information transmission devices are not reconnected.

  Here, an example of the operation of the optical transmission system 23 will be described with reference to FIG. First, the optical signal 81 output from the first optical transmission device 31 is transmitted to the second optical transmission device 32 by the first optical signal branching unit 43 and the light toward the third optical transmission device 33. The signal 82 is branched into two. If the second optical transmission device 32 and the third optical transmission device 33 are optical signals output to the respective optical transmission devices, the optical signals are taken into the optical transmission devices and converted into electrical signals for information transmission. If it is output to a device and not an optical signal output to each optical transmission device, it is discarded.

  For example, when the optical signal 81 is a transmission request signal to the second optical transmission device 32, the optical signal 82 is discarded in the third optical transmission device 33, and the optical signal 81 in the second optical transmission device 32 is It is converted into an electric signal 80 and output to the information transmission device 37 connected to the second optical transmission device 32.

  The information transmission device 37 that has received the electrical signal 80 responds to the transmission request and outputs the electrical signal 79 toward the second optical transmission device 32. The second optical transmission device 32 that has received the electrical signal 79 converts the electrical signal 79 into an optical signal 86 and outputs it to the first optical transmission device 31. A part of the optical signal 86 is branched by the second optical signal branching means 45 into an optical signal 84 output toward the fourth optical transmission device 34. The branched optical signal 84 is received by the fourth optical transmission device 34.

  At this time, for example, the fourth optical transmission device 34 converts the optical signal 84 into an electric signal, and outputs a part of the converted electric signal to the control unit 56 as the second optical signal output detection signal 93. The control unit 56 that has detected the second optical signal output detection signal 93 outputs a voltage signal as the second optical switch control signal 94 to the second optical switch 55 to forcibly block the optical signal 83.

  The optical signal 86 output from the second optical transmission device 32 is coupled toward the first optical transmission device 31 by the first optical signal coupling means 44. Since the optical signal 83 output from the third optical transmission device 33 to the first optical transmission device 31 is blocked by the second optical switch 55, the optical signal 83 and the optical signal 86 collide with each other. There is nothing to do.

  In the above operation example, the transmission order of the optical signals 83 output from the third optical transmission device 33 to the first optical transmission device 31 is determined from the second optical transmission device 32 to the first optical transmission device 31. However, as described in the first embodiment, the transmission order can naturally be set in reverse. Further, by providing the second optical signal coupling means 46, when the optical signal 83 is output from the third optical transmission device 33 toward the first optical transmission device 31, the fourth optical transmission device. The second optical transmission device 32 is output until the third optical transmission device 33 finishes outputting the optical signal 83 by outputting the optical signal 85 as an output stop signal from the 34 toward the second optical transmission device 32. The output of the optical signal 86 can also be stopped.

  In the optical transmission system 23 that performs the above operation, the information transmission device 38 connected to the third optical transmission device 33 is, for example, a camera using a CCD sensor, a sensor that detects opening and closing of a window, and a room temperature. Information transmission equipment that does not send and receive information frequently, such as temperature sensors, security sensors such as smoke sensors that detect smoke generated indoors, and meter reading meters that measure the amount of gas, water, and electricity used. It is desirable to be. These information transmission devices have a smaller number of times of information output than information terminals such as computers, and the traffic of the existing optical transmission system configured by the first optical transmission device 31 and the second optical transmission device 32 is reduced. This is because it does not give much influence and it is not necessary to use a special control means relating to the output of the optical signal.

  In addition, the transmission order of information can be set for each security sensor and meter-reading meter. For example, since the information output from the meter-reading meter is not urgent, the transmission order is set low. On the other hand, since the information output from the smoke sensor is urgent, such as fire detection information, the transmission order is set higher than the transmission order of information output from any information transmission device. As described above, the optical transmission system 23 can freely set the information transmission order.

  Further, for example, the optical transmission system 23 can perform an operation that takes time to transmit an optical signal, such as operating a CCD camera installed indoors according to an instruction from the outside.

It is the schematic which showed an example of the structure of the optical transmission system which concerns on this invention. It is the schematic which showed an example of the structure of the optical transmission system which concerns on this invention. It is the schematic which showed an example of the structure of the optical transmission system which concerns on this invention. It is a schematic block diagram of an optical directional coupler. It is a schematic block diagram of an optical signal branching unit and an optical signal coupling unit configured by applying a WDM filter.

Explanation of symbols

10, 20, 23 Optical transmission system 11, 21, 24 Optical transmission unit 31 First optical transmission device 32 Second optical transmission device 33 Third optical transmission device 34 Fourth optical transmission device 35, 36, 37, 38 Information transmission equipment 41 Optical signal branching means 42 Optical signal coupling means 43 First optical signal branching means 44 First optical signal coupling means 45 Second optical signal branching means 46 Second optical signal coupling means 51, 53, 56 control unit 52 optical switch 54 first optical switch 55 second optical switch 61 optical signal output detection signal 62 optical switch control signal 71, 72, 73, 74, 75 optical signal 76, 77, 78, 79, 80 electricity Signal 81, 82, 83, 84, 85, 86, 87, 88 Optical signal 91 First optical signal output detection signal 92 First optical switch control signal 93 Second optical signal output detection signal 4 the second optical switch control signal 95 optical transmission device control signal 100,301,302,303,304 optical directional coupler 101 optical waveguide 102 light 201, 202, 203 WDM filter

Claims (13)

A first optical transmission apparatus that performs point-to-point transmission in the physical layer;
A second optical transmission apparatus that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission apparatus;
An optical transmission system comprising: m (m is a natural number) optical transmission units connected in cascade between the first optical transmission device and the second optical transmission device. ,
The nth (n is a natural number less than or equal to m) optical transmission unit includes
A (n + 2) th optical transmission device that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission device;
A downstream optical signal input from the first optical transmission device side to the nth optical transmission unit is branched into two toward the second optical transmission device and to the (n + 2) th optical transmission device. N-th optical signal branching means;
Said second of said first optical transmission upstream of the optical signal output from the optical transmission apparatus of the uplink optical signal and the from the side of the optical transmission apparatus is inputted to the optical transmission unit of the first n second (n + 2) Nth optical signal coupling means coupled towards the device;
When an upstream optical signal is output from the (n + 2) th optical transmission device to the first optical transmission device, it is input to the nth optical transmission unit from the second optical transmission device side. N-th optical signal blocking means for blocking an upstream optical signal to be performed at a preceding stage of the n-th optical signal coupling means;
Is provided ,
The nth optical transmission unit receives the downstream optical signal from the first optical transmission device by the (n + 2) th optical transmission device and couples it to the second optical transmission device. The upstream optical signal from the optical transmission device is coupled to the first optical transmission device, and when the (n + 2) th optical transmission device outputs the upstream optical signal, the second optical transmission device An optical transmission system characterized in that the upstream optical signal is blocked and the upstream optical signal from the (n + 2) th optical transmission device is coupled to the first optical transmission device . The nth optical signal blocking means includes an nth optical switch that blocks or conducts an optical signal, and an nth control unit that controls the operation of the nth optical switch,
The n-th optical switch is inserted between the n-th optical signal coupling means and the second optical transmission device, and the n-th control unit is connected to the (n + 2) -th optical transmission device. When it is detected that an upstream optical signal is output toward the first optical transmission device, the upstream optical signal from the second optical transmission device is controlled by controlling the operation of the nth optical switch. The optical transmission system according to claim 1, wherein the optical transmission system is cut off. A first optical transmission apparatus that performs point-to-point transmission in the physical layer;
A second optical transmission apparatus that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission apparatus;
An optical transmission system comprising p (p is a natural number) optical transmission units connected in cascade between the first optical transmission device and the second optical transmission device. ,
The q-th optical transmission unit (q is a natural number equal to or less than p) includes:
A (2q + 1) th optical transmission apparatus that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission apparatus;
A (2q + 2) th optical transmission device capable of bidirectional point-to-point transmission in the physical layer with the second optical transmission device;
A downstream optical signal input to the q-th optical transmission unit from the first optical transmission device side is branched into two toward the second optical transmission device and to the (2q + 1) -th optical transmission device. (2q-1) th optical signal branching means;
The upstream optical signal input to the q-th optical transmission unit from the second optical transmission device side is branched into two toward the first optical transmission device and to the (2q + 2) optical transmission device. 2nd q optical signal branching means;
Light of the first 2q optical signal the by branching means first upstream optical signals branched toward the optical transmission device and the second (2q + 1) upstream of the optical signal to the first 2q output from the optical transmission device Q-th optical signal coupling means coupled from the signal branching means toward the first optical transmission apparatus on the first optical transmission apparatus side;
When the (2q + 1) th optical transmission device outputs an upstream optical signal toward the first optical transmission device, the second optical transmission device outputs the first optical transmission device toward the first optical transmission device. An upstream optical signal and a downstream optical signal output from the first optical transmission device to the second optical transmission device are blocked in the qth optical transmission unit, and the second q optical signal When the (2q + 2) optical transmission device receives an optical signal branched from an upstream optical signal from the second optical transmission device side by the branching means, the (2q + 1) optical transmission device is Q-th optical signal control means for stopping output of an upstream optical signal output to the first optical transmission device;
An optical transmission system equipped with A first optical transmission apparatus that performs point-to-point transmission in the physical layer;
A second optical transmission apparatus that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission apparatus;
An optical transmission system comprising p (p is a natural number) optical transmission units connected in cascade between the first optical transmission device and the second optical transmission device. ,
The q-th optical transmission unit (q is a natural number equal to or less than p) includes:
A (2q + 1) th optical transmission apparatus that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission apparatus;
A (2q + 2) th optical transmission device capable of bidirectional point-to-point transmission in the physical layer with the second optical transmission device;
A downstream optical signal input to the q-th optical transmission unit from the first optical transmission device side is branched into two toward the second optical transmission device and to the (2q + 1) -th optical transmission device. (2q-1) th optical signal branching means;
The upstream optical signal input to the q-th optical transmission unit from the second optical transmission device side is branched into two toward the first optical transmission device and to the (2q + 2) optical transmission device. 2nd q optical signal branching means;
The upstream optical signal branched toward the first optical transmission device by the second q optical signal branching means and the upstream optical signal output from the (2q + 1) optical transmission device are used as the second q light. Q-th optical signal coupling means coupled from the signal branching means toward the first optical transmission apparatus on the first optical transmission apparatus side;
When the (2q + 1) th optical transmission device outputs an upstream optical signal toward the first optical transmission device, the second optical transmission device outputs the first optical transmission device toward the first optical transmission device. An upstream optical signal and a downstream optical signal output from the first optical transmission device to the second optical transmission device are blocked in the qth optical transmission unit, or the second q optical signal When the (2q + 2) optical transmission device receives an optical signal branched from an upstream optical signal from the second optical transmission device side by the branching means, the (2q + 1) optical transmission device is Q-th optical signal control means for stopping output of an upstream optical signal output to the first optical transmission device;
An optical transmission system equipped with The q-th optical signal control means includes a (2q-1) th optical switch for blocking or conducting an optical signal, a secondq optical switch for blocking or conducting an optical signal, and the (2q-1) th optical switch. A q-th control unit that controls operations of the optical switch, the second q-th optical switch, and the (2q + 1) -th optical transmission device,
The (2q-1) th optical switch is inserted between the 2qth optical signal branching means and the qth optical signal coupling means, and the 2qth optical switch is connected to the (2q-1) th optical switch. ) Between the optical signal branching means and the second optical transmission device,
The q-th control unit outputs an upstream optical signal output from the second optical transmission device to the first optical transmission device and the first optical transmission device to the second optical transmission device. And controlling the (2q-1) -th optical switch and the second-q optical switch to shut down the downstream optical signal output toward the second-th optical switch when shut-off in the q-th optical transmission unit ,
Control is performed to stop the operation of the (2q + 1) th optical transmission apparatus when the (2q + 1) th optical transmission apparatus stops outputting the upstream optical signal output to the first optical transmission apparatus. The optical transmission system according to claim 3 or 4 , wherein A first optical transmission apparatus that performs point-to-point transmission in the physical layer;
A second optical transmission apparatus that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission apparatus;
An optical transmission system comprising: s (s is a natural number) optical transmission units connected in cascade between the first optical transmission device and the second optical transmission device. ,
The t-th optical transmission unit (t is a natural number equal to or less than s) includes:
A (2t + 1) th optical transmission device that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission device;
A (2t + 2) optical transmission device capable of bidirectional point-to-point transmission in the physical layer with the second optical transmission device;
A downstream optical signal input to the t-th optical transmission unit from the first optical transmission device side is branched into two toward the second optical transmission device and to the (2t + 1) -th optical transmission device. (2t-1) th optical signal branching means;
The upstream optical signal input to the t-th optical transmission unit from the second optical transmission device side is branched into two toward the first optical transmission device and to the (2t + 2) optical transmission device. A second t optical signal branching means;
Light of the second 2t of the optical signal the by branching means first upstream optical signals branched toward the optical transmission device and the second (2t + 1) upstream of the optical signal to the first 2t outputted from the optical transmission device T-th optical signal coupling means coupled to the first optical transmission device on the side of the first optical transmission device from the signal branching unit;
When the (2t + 1) -th optical transmission device outputs an upstream optical signal toward the first optical transmission device, the second optical transmission device outputs the first optical transmission device toward the first optical transmission device. The upstream optical signal is blocked in the t-th optical transmission unit, and the optical signal branched from the upstream optical signal from the second optical transmission device side by the second t optical signal branching means is T-th optical signal blocking means for blocking an upstream optical signal output to the first optical transmission device by the (2t + 1) optical transmission device when received by the (2t + 2) optical transmission device ; ,
An optical transmission system equipped with A first optical transmission apparatus that performs point-to-point transmission in the physical layer;
A second optical transmission apparatus that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission apparatus;
An optical transmission system comprising: s (s is a natural number) optical transmission units connected in cascade between the first optical transmission device and the second optical transmission device. ,
The t-th optical transmission unit (t is a natural number equal to or less than s) includes:
A (2t + 1) th optical transmission device that performs point-to-point transmission bidirectionally in the physical layer with the first optical transmission device;
A (2t + 2) optical transmission device capable of bidirectional point-to-point transmission in the physical layer with the second optical transmission device;
A downstream optical signal input to the t-th optical transmission unit from the first optical transmission device side is branched into two toward the second optical transmission device and to the (2t + 1) -th optical transmission device. (2t-1) th optical signal branching means;
The upstream optical signal input to the t-th optical transmission unit from the second optical transmission device side is branched into two toward the first optical transmission device and to the (2t + 2) optical transmission device. A second t optical signal branching means;
The upstream optical signal branched to the first optical transmission device by the second t optical signal branching unit and the upstream optical signal output from the (2t + 1) optical transmission device are used as the second t light. T-th optical signal coupling means coupled to the first optical transmission device on the side of the first optical transmission device from the signal branching unit;
When the (2t + 1) -th optical transmission device outputs an upstream optical signal toward the first optical transmission device, the second optical transmission device outputs the first optical transmission device toward the first optical transmission device. The upstream optical signal is blocked in the t-th optical transmission unit, or the optical signal branched from the upstream optical signal from the second optical transmission device side by the second t optical signal branching means is T-th optical signal blocking means for blocking an upstream optical signal output to the first optical transmission device by the (2t + 1) optical transmission device when received by the (2t + 2) optical transmission device; ,
An optical transmission system equipped with The t-th optical signal blocking means includes a (2t-1) optical switch for blocking or conducting an optical signal, a second t optical switch for blocking or conducting an optical signal, and the (2t-1) th optical switch. An t-th control unit for controlling the operation of the optical switch and the second t-th optical switch,
The (2t-1) optical switch is inserted between the t-th optical signal coupling means and the second t optical signal branching means, and the second t optical switch is the t-th optical signal. Inserted between the coupling means and the (2t + 1) th optical transmission device,
The t-th control unit is configured to block the upstream optical signal output from the second optical transmission device to the first optical transmission device in the t-th optical transmission unit. 2t-1) is controlled to cut off the optical switch ,
The second (2t + 1) optical transmission device is controlled so as to cut off the second t optical switch when blocking an upstream optical signal output to the first optical transmission device. Item 8. The optical transmission system according to Item 6 or 7 . An optical transmission device that performs bidirectional point-to-point transmission in a physical layer with an opposing optical transmission device;
The downstream optical signal that is disposed between the opposing optical transmission device and the other optical transmission device that is opposed to each other and that is output from the opposing optical transmission device is directed toward the other optical transmission device and the Optical signal branching means for branching into the optical transmission device;
The relative other is disposed between the optical transmission device and said opposing optical transmission device, the opposing other of the output upstream from the optical transmission apparatus optical signal and the uplink of the light output from the optical transmission device An optical signal coupling means for coupling a signal toward the opposite optical transmission device;
An upstream signal connected to the optical signal coupling unit between the optical signal coupling unit and the other optical transmission device opposite to the optical signal coupling unit and output to the opposite optical transmission device from the opposite optical transmission device An optical switch for blocking or conducting an optical signal;
A control unit that controls the operation of the optical switch to block the optical signal when it is detected that an upstream optical signal is output from the optical transmission device toward the opposite optical transmission device;
Equipped with a,
The downstream optical signal from the opposing optical transmission device is received by the optical transmission device and coupled to the other opposing optical transmission device, and the upstream optical signal from the opposing optical transmission device is the relative And when the optical transmission device outputs an upstream optical signal, the upstream optical signal from the opposite optical transmission device is blocked and the upstream optical signal from the optical transmission device is blocked. An optical transmission unit for coupling an optical signal to the opposite optical transmission device . A first optical transmission device that performs bidirectional point-to-point transmission in a physical layer with an opposing optical transmission device;
It is arranged between the opposing optical transmission device and another opposing optical transmission device, and can perform point-to-point transmission in both directions in the physical layer between the opposing optical transmission devices. A second optical transmission device,
The downstream optical signal that is disposed between the opposing optical transmission device and the other optical transmission device and that is output from the opposing optical transmission device is directed toward the other optical transmission device. First optical signal branching means for branching into two to the first optical transmission device;
The upstream optical signal that is disposed between the opposing optical transmission device and the other optical transmission device that is opposed to each other and that is output from the other optical transmission device that is opposed to the second optical transmission device; Second optical signal branching means that branches into two toward the opposite optical transmission device;
An upstream optical signal disposed between the second optical signal branching unit and the opposing optical transmission device, and branched to the opposing optical transmission device by the second optical signal branching unit; Optical signal coupling means for coupling an upstream optical signal output from one optical transmission device toward the opposite optical transmission device;
An upstream optical signal inserted between the second optical signal branching unit and the optical signal coupling unit and output from the other optical transmission device to the opposite optical transmission device is cut off or conducted. A first optical switch that allows
A downstream optical signal inserted between the first optical signal branching means and the other optical transmission device opposite to the optical signal and outputted from the opposite optical transmission device toward the other optical transmission device opposite to the first optical signal branching unit. A second optical switch for blocking or conducting;
Controlling the operation of the first optical switch and the second optical switch when detecting that an upstream optical signal is output from the first optical transmission device to the opposite optical transmission device; An upstream optical signal output from the other optical transmission device to the opposite optical transmission device and a downstream optical signal output from the opposite optical transmission device to the other optical transmission device The second optical transmission device receives the optical signal that is blocked from the upstream optical signal output from the opposite side of the other optical transmission device by the second optical signal branching means while blocking the optical signal. A control unit that controls the operation of the first optical transmission device when the first optical transmission device is stopped, and stops the output of the upstream optical signal output from the first optical transmission device to the opposite optical transmission device;
An optical transmission unit comprising: A first optical transmission device that performs bidirectional point-to-point transmission in a physical layer with an opposing optical transmission device;
It is arranged between the opposing optical transmission device and another opposing optical transmission device, and can perform point-to-point transmission in both directions in the physical layer between the opposing optical transmission devices. A second optical transmission device,
The downstream optical signal that is disposed between the opposing optical transmission device and the other optical transmission device and that is output from the opposing optical transmission device is directed toward the other optical transmission device. First optical signal branching means for branching into two to the first optical transmission device;
The upstream optical signal that is disposed between the opposing optical transmission device and the other optical transmission device that is opposed to each other and that is output from the other optical transmission device that is opposed to the second optical transmission device; Second optical signal branching means that branches into two toward the opposite optical transmission device;
An upstream optical signal disposed between the second optical signal branching unit and the opposing optical transmission device, and branched to the opposing optical transmission device by the second optical signal branching unit; Optical signal coupling means for coupling an upstream optical signal output from one optical transmission device toward the opposite optical transmission device;
An upstream optical signal inserted between the second optical signal branching unit and the optical signal coupling unit and output from the other optical transmission device to the opposite optical transmission device is cut off or conducted. A first optical switch that allows
A downstream optical signal inserted between the first optical signal branching means and the other optical transmission device opposite to the optical signal and outputted from the opposite optical transmission device toward the other optical transmission device opposite to the first optical signal branching unit. A second optical switch for blocking or conducting;
Controlling the operation of the first optical switch and the second optical switch when detecting that an upstream optical signal is output from the first optical transmission device to the opposite optical transmission device; An upstream optical signal output from the other optical transmission device to the opposite optical transmission device and a downstream optical signal output from the opposite optical transmission device to the other optical transmission device The second optical transmission device receives an optical signal that is blocked from an upstream optical signal output from the opposite optical transmission device side by the second optical signal branching means by blocking the optical signal. A control unit that controls the operation of the first optical transmission device when the first optical transmission device is stopped, and stops the output of the upstream optical signal output from the first optical transmission device to the opposite optical transmission device;
An optical transmission unit comprising: A first optical transmission device that performs bidirectional point-to-point transmission in a physical layer with an opposing optical transmission device;
It is arranged between the opposing optical transmission device and another opposing optical transmission device, and can perform point-to-point transmission in both directions in the physical layer between the opposing optical transmission devices. A second optical transmission device,
The downstream optical signal that is disposed between the opposing optical transmission device and the other optical transmission device and that is output from the opposing optical transmission device is directed toward the other optical transmission device. First optical signal branching means for branching into two to the first optical transmission device;
The upstream optical signal that is disposed between the opposing optical transmission device and the other optical transmission device that is opposed to each other and that is output from the other optical transmission device that is opposed to the second optical transmission device; Second optical signal branching means that branches into two toward the opposite optical transmission device;
An upstream optical signal disposed between the second optical signal branching unit and the opposing optical transmission device, and branched to the opposing optical transmission device by the second optical signal branching unit; Optical signal coupling means for coupling an upstream optical signal output from one optical transmission device toward the opposite optical transmission device;
An upstream optical signal inserted between the second optical signal branching unit and the optical signal coupling unit and output from the other optical transmission device to the opposite optical transmission device is cut off or conducted. A first optical switch that allows
A second optical signal inserted between the first optical transmission device and the optical signal coupling means and configured to block or conduct an upstream optical signal output from the first optical transmission device toward the optical signal coupling means; With an optical switch,
When it is detected that an upstream optical signal is output from the first optical transmission device to the opposite optical transmission device, the operation of the first optical switch is controlled to detect the other light The upstream optical signal output from the transmission device to the opposite optical transmission device is blocked, and the upstream optical signal output from the opposite optical transmission device side by the second optical signal branching unit When the second optical transmission device receives the optical signal branched from the signal, the operation of the second optical switch is controlled so that the first optical transmission device is directed to the opposite optical transmission device. A control unit that blocks an output optical signal that is output ;
An optical transmission unit comprising: A first optical transmission device that performs bidirectional point-to-point transmission in a physical layer with an opposing optical transmission device;
It is arranged between the opposing optical transmission device and another opposing optical transmission device, and can perform point-to-point transmission in both directions in the physical layer between the opposing optical transmission devices. A second optical transmission device,
The downstream optical signal that is disposed between the opposing optical transmission device and the other optical transmission device and that is output from the opposing optical transmission device is directed toward the other optical transmission device. First optical signal branching means for branching into two to the first optical transmission device;
The upstream optical signal that is disposed between the opposing optical transmission device and the other optical transmission device that is opposed to each other and that is output from the other optical transmission device that is opposed to the second optical transmission device; Second optical signal branching means that branches into two toward the opposite optical transmission device;
An upstream optical signal disposed between the second optical signal branching unit and the opposing optical transmission device, and branched to the opposing optical transmission device by the second optical signal branching unit; Optical signal coupling means for coupling an upstream optical signal output from one optical transmission device toward the opposite optical transmission device;
An upstream optical signal inserted between the second optical signal branching unit and the optical signal coupling unit and output from the other optical transmission device to the opposite optical transmission device is cut off or conducted. A first optical switch that allows
A second optical signal inserted between the first optical transmission device and the optical signal coupling means and configured to block or conduct an upstream optical signal output from the first optical transmission device toward the optical signal coupling means; With an optical switch,
When it is detected that an upstream optical signal is output from the first optical transmission device to the opposite optical transmission device, the operation of the first optical switch is controlled to detect the other light The upstream optical signal output from the transmission apparatus toward the opposite optical transmission apparatus is blocked, or the upstream optical signal output from the opposite optical transmission apparatus side by the second optical signal branching unit When the second optical transmission device receives the optical signal branched from the signal, the operation of the second optical switch is controlled so that the first optical transmission device is directed to the opposite optical transmission device. A control unit that blocks an output optical signal that is output;
An optical transmission unit comprising:

Images