KR20090113469A - Media oriented systems transport optical connector including indicators for showing states of transmitting and receiving optical signals - Google Patents

Abstract

PURPOSE: A media oriented systems transport optical connector including indicators for showing states of transmitting and receiving optical signals is provided to easily supply a state of an optical signal for MOST(Media oriented systems transport) communication through an indicator. CONSTITUTION: A light emitting unit(160) converts a transmission MOST signal received from a MOST communication unit(201) to a transmission optical signal. An optical branching unit(120,130) branches the transmission optical signal incident through an input port into the first and second branch optical signals. An optical divider outputs the first branch optical signal to the first output port. The optical divider outputs the second branch optical signal to the second output port.

Description

Media oriented systems transport optical connector including indicators for showing states of transmitting and receiving optical signals

The present invention relates to devices used for MOST (Media Oriented System Transport) communication, and more particularly, to a MOST optical connector.

Recently, a plurality of multimedia devices having various functions are installed in a vehicle to provide convenience to a user. Since multimedia devices must communicate with vehicle accessories (e.g., speakers, display devices, etc.), or communication between the multimedia devices must be performed, complicated wiring work is required to connect the multimedia devices and the accessories together. need. However, due to the limited interior space of the vehicle, it is difficult to perform complicated wiring work. In order to simplify such a complicated wiring work, a communication method widely applied to a vehicle is a data communication method using a MOST network. In the data communication method using a MOST network, multimedia devices and accessory devices are connected to each other through a single optical cable, and communication data between the devices is converted into an optical signal to be transmitted to each other through the optical cable.

1 is a diagram conceptually illustrating an example of a MOST network configuration configured by multimedia devices including a conventional MOST optical connector. Multimedia devices 11-51 are electrically connected to MOST optical connectors 12-52, respectively, for MOST communication. In FIG. 1, one multimedia device (eg 11) and one MOST optical connector (eg 12) form one MOST node (eg 10). By the user, one of the MOST nodes 10-50 can be set as a master of the MOST network. As shown in FIG. 1, typically, a MOST network consists of a single ring network topology. Therefore, when each MOST node 10 to 50 receives an optical signal, the MOST node 10 to 50 must transmit an optical signal corresponding to the received optical signal to another MOST node even if the received optical signal is irrelevant to its operation. In FIG. 1, the movement path of the optical signal between the MOST nodes 10-50 is indicated by an arrow. In the MOST network composed of the annular network topology, even if an error occurs in any of the MOST nodes 10-50, the entire MOST network may fail. In this case, it is very difficult to find the corresponding MOST node in which the error occurs among the MOST nodes 10 to 50 because the state of the transmission / reception optical signals of the respective MOST optical connectors 12 to 52 cannot be confirmed.

To find the corresponding MOST node in which the error occurred, the inspector disconnects each MOST optical connector 12-52 from the MOST network and directly checks whether the transmission optical signal of the MOST optical connectors 12-52 is outputting normally. Should be. However, it is very dangerous for the inspector to see the transmission optical signal of the MOST optical connector directly, even if the transmission optical signal of the MOST optical connector satisfies a specification suitable for industrial use. Therefore, although a separate device for checking the state of the transmission optical signal of the MOST optical connector from time to time is required, until now, the MOST communication system is not provided with a device for displaying the state of the optical signal. Meanwhile, an apparatus for displaying a state of an optical signal may be configured by using an electric element such as a light emitting diode (LED). In this case, however, additional electrical elements are required to configure the device for displaying the state of the optical signal, so that its manufacturing cost increases, and the elements constituting the device for displaying the state of the optical signal are active. Since the device consumes more current.

Accordingly, the technical problem to be achieved by the present invention includes an indicator for visually displaying an optical signal branched from the optical signal for MOST communication without additional power consumption, thereby allowing the user to easily check the state of the optical signal for MOST communication. An optical connector is provided.

The MOST optical connector according to the present invention for achieving the above technical problem includes a light emitting portion, a light splitter, a light collecting portion, an indicator, and a light receiving portion. The light emitting unit converts the transmission MOST signal received from the MOST communication unit into a transmission optical signal and outputs it. The optical splitter includes an input port and first and second output ports, branch the transmission optical signal incident through the input port into first and second branch optical signals, and split the first branch optical signal to the first output port. And outputs a second branch optical signal to the second output port. The condenser condenses the received optical signal incident through the first optical fiber from the MOST optical connector of one of the external MOST nodes constituting the MOST network, outputs the first condensed optical signal, and condenses the first branch optical signal. 2 Output a condensing light signal. The indicator visually displays the state of the second branch optical signal. The light receiving unit converts the first condensing optical signal into a received MOST signal and outputs it to the MOST communication unit. The second condensed optical signal is transmitted to the MOST optical connector of one of the external MOST nodes via the second optical fiber, and the wavelength of the second branch optical signal is included in the wavelength range of visible light.

As described above, the MOST optical connector according to the present invention includes an indicator for visually displaying the optical signal branched from the optical signal for MOST communication without additional power consumption, so that the user can easily display the state of the optical signal for MOST communication through the indicator. You can check it.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various forms, and only the present embodiments are intended to complete the disclosure of the present invention and to those skilled in the art. It is provided for complete information.

2 is a schematic configuration diagram of a MOST optical connector according to an embodiment of the present invention. In FIG. 2, the MOST optical connector 101, the MOST communication unit 201, and the electronic device 202 form one MOST node. The MOST optical connector 101 includes a light collecting unit 110, light splitters 120 and 130, indicators 140 and 150, a light emitting unit 160, and a light receiving unit 170. The MOST optical connector 101 is a pigtail-type type MOST optical connector in which the light collecting part 110, the light emitting part 140, and the light receiving part 150 are connected to each other by an optical fiber. In contrast, a MOST optical connector in which a light collecting portion and a light emitting portion and a light receiving portion are integrally formed is an in-module type MOST optical connector. In the present invention, a pigtail type MOST optical connector is used.

The light collecting unit 110 is connected to one MOST optical connector (not shown) of external MOST nodes (not shown) constituting the MOST network through the optical fibers 181 and 182. In addition, the light collecting unit 110 is connected to the light splitters 120 and 130 through the optical fibers 183 and 184, respectively. The condenser lenses 111 and 112 are installed in the condenser 110. The condenser lens 111 condenses the received optical signal RXO incident through the optical fiber 181 from one of the MOST optical connectors (not shown) of the external MOST nodes (not shown) constituting the MOST network. Output the optical signal FRXO. The condenser lens 112 condenses the branched optical signal DTX1 incident through the optical fiber 183 from the optical splitter 120, and outputs the condensed optical signal FTXO to the optical fiber 182. The condensing optical signal FTXO is transmitted to the MOST optical connector of one of the external MOST nodes via the optical fiber 182.

The optical splitter 120 includes an input port 121 and output ports 122 and 123. The input port 121 of the optical splitter 120 is connected to the light emitting unit 160 through the optical fiber 185. The output port 122 of the light splitter 120 is connected to the light collecting unit 110 through the optical fiber 183. The output port 123 of the light splitter 120 is connected to the indicator 140. The optical splitter 120 branches the transmission optical signal TXO from the light emitting unit 160 incident through the input port 121 into the branch optical signals DTX1 and DTX2. At this time, the light amount of the branch light signal DTX1 is greater than the light amount of the branch light signal DTX2. For example, the split ratio of the optical splitter 120 may be set to 9: 1. In this case, the light amount of the branch light signal DTX1 corresponds to 9 times the light amount of the branch light signal DTX2. The optical splitter 120 outputs the branch optical signal DTX1 to the output port 122, and outputs the branch optical signal DTX2 to the output port 123. The wavelength of the branch light signal DTX2 is included in the wavelength range of visible light.

The optical splitter 130 includes an input port 131 and output ports 132 and 133. The input port 131 of the optical splitter 130 is connected to the light collecting unit 110 through the optical fiber 184. The output port 132 of the optical splitter 130 is connected to the light receiver 170 through the optical fiber 186. The output port 133 of the light splitter 130 is connected to the indicator 150. The optical splitter 130 branches the condensing optical signal FRXO from the condenser 110 incident through the input port 131 into the branch optical signals DRX1 and DRX2. At this time, the light amount of the branch light signal DRX1 is greater than the light amount of the branch light signal DRX2. For example, the split ratio of the optical splitter 130 may be set to 9: 1. In this case, the light amount of the branch light signal DRX1 corresponds to 9 times the light amount of the branch light signal DRX2. The optical splitter 130 outputs the branch optical signal DRX1 to the output port 132, and outputs the branch optical signal DRX2 to the output port 133. The wavelength of the branch light signal DRX2 is included in the wavelength range of visible light.

The indicator 140 visually displays the state of the branch optical signal DTX2. Indicator 140 may be implemented as an optical fiber including ends 141 and 142. Hereinafter, the indicator 140 is referred to as the optical fiber 140. The end 141 of the optical fiber 140 is connected to the output port 123 of the optical splitter 120. The end 142 of the optical fiber 140 has a longitudinal cross section 143 that is inclinedly cut at a set slope. The branch optical signal DTX2 propagates through the optical fiber 140, is refracted at an angle θ1 (see FIG. 3) set at the end surface 143, and is emitted to the outside. Referring to FIG. 3, the traveling path of the branch optical signal DTX2 at the end 142 of the optical fiber 140 will be described in more detail. FIG. 3 is an enlarged cross-sectional view of the portion indicated by “A” of the indicator (ie, optical fiber) 140 shown in FIG. 2. As shown in FIG. 3, the branched optical signal DTX2 propagated through the optical fiber 140 is refracted by an angle θ1 at the end surface 143 of the optical fiber 140, and the refracted branched optical signal DTX2 ′. ) Is emitted to the outside.

On the other hand, a part of the branch optical signal DTX2 is reflected from the end surface 143 without being emitted to the outside, and the reflected branch optical signal DTX2 ″ is reincident to the inside of the optical fiber 140. In this case, when the branched optical signal DTX2 ″ is reflected from the end surface 143, the beam is refracted by the angle θ2 and re-entered into the optical fiber 140, and thus, the influence on the branched optical signal DTX2 that is the original signal. This can be reduced. In more detail, the branched optical signal DTX2 ″ refracted by the angle θ2 and reincident does not propagate far through the optical fiber 140. Therefore, the influence of the branch optical signal DTX2 ″ on the branch optical signal DTX2 may be reduced.

In contrast to the optical fiber 140, the comparative optical fiber 190 shown in FIG. 4 has a longitudinal section 191 cut at right angles. As such, when the end surface 191 forms a right angle to the longitudinal direction of the optical fiber 190, the optical signal X1 propagated through the optical fiber 190 is reflected at an angle of 0 ° from the end surface 191 to be inside the optical fiber 190. Will reenter The optical signal X2 reflected at an angle of 0 ° from the longitudinal section 191 may be parallel to the optical signal X1, which is the original signal, and may propagate far through the optical fiber 190. As a result, the optical signal X2 becomes a noise component that affects the optical signal X1 which is the original signal, thereby distorting the optical signal X1 or generating an error in the optical signal X1.

Meanwhile, in FIG. 3, the sizes of the angles θ1 and θ2 may vary according to the change in the slope of the longitudinal cross-section 143 of the optical fiber 140. Accordingly, the inclination of the longitudinal cross section 143 may be adjusted to minimize the influence of the branch optical signal DTX2 ″ reflected from the longitudinal cross section 143 on the branch optical signal DTX2 as the original signal.

Since the wavelength of the branch optical signal DTX2 is included in the wavelength range of the visible light, the inspector may observe the state of the branch optical signal DTX2 at the end surface 143 of the optical fiber 140. For example, the branch optical signal DTX2 may appear as an orange light at the end surface 143. The inspector may check whether the light emitter 160 normally generates the transmission optical signal TXO depending on whether orange light is observed on the end surface 143 of the optical fiber 140. At this time, since the branch optical signal DTX2 ″ is refracted by the longitudinal section 143 and exits to the outside, the branch optical signal DTX2 ″ does not directly enter the eye of the inspector. Therefore, the inspector can safely check the state of the transmission optical signal TXO of the MOST optical connector 101.

The indicator 150 visually displays the state of the branch optical signal DRX2. Indicator 150 may be implemented as an optical fiber including ends 151 and 152. Hereinafter, the indicator 150 is referred to as the optical fiber 150. The end 151 of the optical fiber 150 is connected to the output port 133 of the optical splitter 130. The end portion 152 of the optical fiber 150 has a longitudinal section 153 cut inclined at an inclination set similarly to the end 142 of the optical fiber 140 described above. The branch optical signal DRX2 propagates through the optical fiber 150, is refracted at an angle θ1 (see FIG. 3) set at the longitudinal section 153, and is emitted to the outside. Since the traveling path of the branch optical signal DRX2 in the optical fiber 150 is similar to the traveling path of the branch optical signal DTX2 described above with reference to FIG. 3, a detailed description thereof will be omitted.

The light emitting unit 160 converts the transmission MOST signal MTX received from the MOST communication unit 201 into a transmission optical signal TXO and outputs the converted optical signal TTX. The light receiver 170 converts the branch optical signal DRX1 into a received MOST signal MRX and outputs the converted MOST signal MRX to the MOST communication unit 201. In FIG. 2, the MOST optical connector 101 is shown as an example, which includes the optical splitters 120, 130 and the indicators 140, 150, but the MOST optical connector 101 is shown in the optical splitters 120, 130. It may include any one of the 130 and only one of the indicators (140, 150). For example, when the MOST optical connector 101 includes only the optical splitter 120 and the indicator 140, the condensing light signal FRXO output from the condenser 110 is incident on the light receiver 170. As a result, the light receiving unit 170 converts the condensed light signal FRXO into a received MOST signal MRX and outputs it to the MOST communication unit 201. The MOST communication unit 201 converts the received MOST signal MRX into a received data signal (not shown) and outputs it to the electronic device 202, and transmits a transmission data signal (not shown) received from the electronic device 202. The signal is converted into the signal MTX and output to the light emitting unit 160.

5 is a schematic structural diagram of a MOST optical connector according to another embodiment of the present invention. The MOST optical connector 102 includes a light collecting unit 110, light splitters 120 and 130, a light emitting unit 160, a light receiving unit 170, and indicators 210 and 220. The configuration and specific operation of the MOST optical connector 102 are the same as the configuration and specific operation of the MOST optical connector 101 described above except for the indicators 210 and 220. Therefore, in the present embodiment, in order to avoid duplication of description, the configuration of the indicators 210 and 220 will be described. The indicator 210 may include an optical fiber 211 and a transparent cap 212. The optical fiber 211 has ends 213 and 214. The end 213 of the optical fiber 211 is connected to the output port 123 of the optical splitter 120.

The end 214 of the optical fiber 211 has a longitudinal section 215 cut obliquely at a set slope. The transparent cap 212 is fitted with the optical fiber 211 at the end 214. Referring to FIG. 6, there is shown an enlarged cross-sectional view of the portion labeled "B" of the indicator 210. The transparent cap 212 is fitted to surround the end 214 of the optical fiber 211. The transparent cap 212 may be formed of a plastic material. The transparent cap 212 allows the light of the branched optical signal DTX2, which is somewhat spread from the end surface 215 of the optical fiber 211, to be seen more clearly. Therefore, the inspector can more easily check the state of the transmission optical signal TXO of the MOST optical connector 102. The indicator 220 may include an optical fiber 221 and a transparent cap 222. The configuration and operation of the optical fiber 221 and the transparent cap 222 is similar to the configuration and operation of the optical fiber 211 and the transparent cap 212 described above, a detailed description thereof will be omitted.

Meanwhile, in FIG. 5, the MOST optical connector 102 including the optical splitters 120 and 130 and the indicators 210 and 220 is shown as an example, but the MOST optical connector 102 is shown as the optical splitters ( It may include any one of the 120 and 130 and only one of the indicators 210 and 220. For example, when the MOST optical connector 102 includes only the optical splitter 120 and the indicator 210, the condensing light signal FRXO output from the condenser 110 is incident on the light receiver 170. As a result, the light receiving unit 170 converts the condensed light signal FRXO into a received MOST signal MRX and outputs it to the MOST communication unit 201.

FIG. 7A is a view showing an example of the appearance of the MOST optical connector shown in FIG. 2 or FIG. 5, and shows a case in which the indicators 140 or 210, 150, or 220 are embedded in the MOST optical connector 101 or 102. In this case, as illustrated in FIG. 7A, display windows 144 and 154 may be formed on one exterior surface of the MOST optical connector 101 or 102. The examiner may check the status of the transmit and receive optical signals displayed by the indicators 140 or 210, 150 or 220 through the display windows 144 and 154.

FIG. 7B is a view showing another example of the appearance of the MOST optical connector shown in FIG. 2 or 5, showing a case in which the indicators 140 or 210, 150 or 220 are separated from the MOST optical connector 101 or 102. . In this case, the indicators 140 or 210, 150 or 220 are housed in a separate housing 103. Display windows 144 and 154 are formed on one surface of the housing 103. Indicators 140 or 210, 150 or 220 received within the housing 103 are connected to the MOST optical connector 101 or 102 via optical fibers 140 or 211, 150 or 221. The housing 103 can be installed at a location desired by the user (eg, the front part inside the vehicle), away from the MOST optical connector 101 or 102.

The above embodiments are for explaining the present invention, and the present invention is not limited to these embodiments, and various embodiments are possible within the scope of the present invention. In addition, although not described, equivalent means will also be referred to as incorporated in the present invention. Therefore, the true scope of the present invention will be defined by the claims below.

1 is a diagram conceptually illustrating an example of a MOST network configuration configured by multimedia devices including a conventional MOST optical connector.

2 is a schematic configuration diagram of a MOST optical connector according to an embodiment of the present invention.

3 is an enlarged cross-sectional view of a portion indicated by "A" of the indicator 140 shown in FIG.

4 is an enlarged cross-sectional view of an end portion of a comparative optical fiber that can be contrasted with the optical fiber shown in FIG.

5 is a schematic structural diagram of a MOST optical connector according to another embodiment of the present invention.

FIG. 6 is an enlarged cross-sectional view of the portion indicated by "B" of the indicator 210 shown in FIG.

FIG. 7A is a diagram showing an example of the appearance of the MOST optical connector shown in FIG. 2 or FIG. 5.

7B is a view showing another example of the appearance of the MOST optical connector shown in FIG. 2 or FIG. 5.

<Explanation of symbols for main parts of drawing>

101, 102: MOST optical connector 110: condenser

120, 130: light splitter 140, 150, 210, 220: indicator

160: light emitting unit 170: light receiving unit

201: MOST communication unit 212, 222: transparent cap

Claims (10)

A light emitting unit for converting a transmission MOST signal received from the MOST communication unit into a transmission optical signal and outputting the converted optical signal; An input port and first and second output ports, branching the transmission optical signal incident through the input port into first and second branch optical signals, and splitting the first branch optical signal into the first output port. An optical splitter for outputting to the second output port and outputting the second split optical signal to the second output port; A first condensing optical signal is output by condensing a received optical signal incident through a first optical fiber from a MOST optical connector of one of the external MOST nodes constituting the MOST network, and condensing the first branch optical signal to concatenate a second optical signal. A condenser for outputting a condensed optical signal; An indicator for visually displaying a state of the second branch optical signal; And A light receiving unit converting the first condensing optical signal into a received MOST signal and outputting the converted MOST signal; And the second condensing optical signal is transmitted through a second optical fiber to a MOST optical connector of one of the external MOST nodes, and the wavelength of the second branch optical signal is within a wavelength range of visible light. The method of claim 1, And the light amount of the first branch optical signal is greater than the light amount of the second branch optical signal. The method of claim 1, The splitting ratio of the optical splitter is 9: 1, And the light amount of the first branch optical signal is nine times the light amount of the second branch optical signal. The method of claim 1, The indicator comprises a third optical fiber, The third optical fiber includes a first end connected to the second output port of the optical splitter, and a second end having a longitudinal cross section cut obliquely at a set slope; And the second branch optical signal propagates through the third optical fiber, is refracted at an angle set in the longitudinal section, and is emitted to the outside. The method of claim 4, wherein And the indicator further comprises a transparent cap fitted to the second end of the third optical fiber. The method of claim 1, An additional optical splitter comprising an input port and first and second output ports, wherein the additional optical splitter splits the first condensing optical signal into third and fourth branching optical signals; And A further indicator for visually displaying a state of the fourth branch optical signal, The first condensed light signal is incident on an input port of the additional optical splitter, the third branch optical signal is emitted from a first output port of the additional optical splitter, and the fourth branch optical signal is Emitted from the second output port of the further optical splitter, And the light receiving unit converts the third branch optical signal into the received MOST signal and outputs the received MOST signal to the MOST communication unit, wherein the wavelength of the fourth branch optical signal is within a wavelength range of visible light. The method of claim 6, And the light amount of the third branch optical signal is greater than the light amount of the fourth branch optical signal. The method of claim 6, The branching ratio of the further optical splitter is 9: 1, And the light amount of the third branch optical signal is nine times the light amount of the fourth branch optical signal. The method of claim 6, The further indicator comprises a third optical fiber, The third optical fiber includes a first end connected to a second output port of the additional optical splitter, and a second end having a longitudinal cross section cut obliquely at a set slope; The fourth branch optical signal is propagated through the third optical fiber, the MOST optical connector is refracted at an angle set in the longitudinal section and emitted to the outside. The method of claim 9, And the additional indicator further comprises a transparent cap fitted to the second end of the third optical fiber.

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