This application is based upon and claims priority under 35 USC 119 from Japanese Patent Application No. 2010-266386, filed Nov. 30, 2010.
1. Technical Field
The present invention relates to a transmitting device and a transmitting/receiving device.
2. Related Art
In an optical transmitting/receiving device for transmitting 1-bit information in a single signal cycle, conventionally, there is known a use of a duo-binary transmitting method for transmitting information without an error while permitting an interference with front and rear bit signals in a transmitting path of an optical fiber.
According to an aspect of the invention, a transmitting device includes a first optical transmitting medium, a second optical transmitting medium, and an optical multiplexing portion. The first optical transmitting medium outputs a first optical signal having a predetermined signal cycle. The second optical transmitting medium outputs a second optical signal obtained by delaying the first optical signal by one cycle of the predetermined signal cycle. The optical multiplexing portion is connected to an output side of the first optical transmitting medium and the second optical transmitting medium and generates a third optical signal obtained by multiplexing the first optical signal and the second optical signal.
Exemplary embodiments of the invention will be described in detail based on the following figures, wherein:
A transmitting/receiving device 1 includes a transmitting device 2, a receiving device 3, and an optical transmitting path 4 for connecting the transmitting device 2 and the receiving device 3 to each other.
The transmitting device 2 includes a photoelectric converting portion 21, an optical branching portion 22, an optical multiplexing portion 23, and first to third optical fibers 201 to 203.
An input terminal 2a is connected to the photoelectric converting portion 21. An electric signal having a binary value of (0, 1) in a predetermined signal cycle is input to the input terminal 2a. The photoelectric converting portion 21 similarly converts the electric signal input to the input terminal 2a into an optical signal having a binary value of (0, 1) and inputs the optical signal to the first optical fiber 201.
In more detail, the photoelectric converting portion 21 causes a light source such as a light-emitting diode to emit a light and inputs a light having a predetermined intensity through the light emission to the first optical fiber 201 when the electric signal input to the input terminal 2a (the electric signal will be hereinafter referred to as an “input signal”) is High(1). Moreover, the photoelectric converting portion 21 does not cause the light source to emit a light and does not input the light to the first optical fiber 201 when the input electric signal is Low(0).
For the light source, it is also possible to apply a resonant-cavity light-emitting diode (RC-LED) or a semiconductor laser. In order to solve a problem of a light emission delay in switching of the signal from the Low to the High, moreover, it is also possible to emit a light on a sufficiently lower level in the case in which the input signal is the Low(0) as compared with the case of the High(1).
The first optical fiber 201 outputs, to the optical branching portion 22, the optical signal input from the photoelectric converting portion 21.
The optical branching portion 22 is constituted by an optical branching coupler formed by fuse welding, melting and elongating two optical fibers, for example. The optical branching portion 22 branches the optical signal output from the first optical fiber 201 and inputs the optical signal thus branched to the second optical fiber 202 and the third optical fiber 203. The second optical fiber 202 is illustrative as a first optical transmitting medium according to the invention and the third optical fiber 203 is illustrative as a second optical transmitting medium according to the invention.
As the first to third optical fibers 201 to 203, it is possible to use Si based POF (Plastic Optical Fiber) having a core diameter of φ 0.48 mm, for example. As the first and second optical transmitting media, moreover, it is also possible to use a quartz fiber (HPCF Hard Plastic Clad Fiber) having a core diameter of φ 0.2 mm.
The second optical fiber 202 and the third optical fiber 203 send the input light to the optical multiplexing portion 23.
The optical multiplexing portion 23 multiplexes the first optical signal output from the second optical fiber 202 and the second optical signal output from the third optical fiber 203 and generates a third optical signal having an intensity obtained by adding intensities of both of the optical signals. The optical multiplexing portion 23 may be implemented by using the optical branching coupler formed by fuse welding, melting and elongating two optical fibers in opposite directions to each other, for example. Moreover, the optical multiplexing portion 23 outputs the third optical signal thus generated to the optical transmitting path 4. The optical signal output from the optical multiplexing portion 23 will be hereinafter referred to as a “transmitting signal”.
The second optical fiber 202 and the third optical fiber 203 have different lengths from input ends on the optical branching portion 22 side to output ends on the optical multiplexing portion 23 side, and the third optical fiber 203 is formed to have a greater optical length than the second optical fiber 202.
As shown in
The length of ΔL is equivalent to a distance at which a light travels along the second optical fiber 202 and the third optical fiber 203 in a time corresponding to a single cycle of an input signal. In other words, the optical signal output from the third optical fiber 203 to the optical multiplexing portion 23 is delayed by a single cycle from the optical signal output from the second optical fiber 202 to the optical multiplexing portion 23.
ΔL to be a difference in an optical length is equivalent to c0/n/f, wherein a refractive index of a core in each of the second optical fiber 202 and the third optical fiber 203 is represented by n, a speed of a light in a vacuum is represented by c0(m/s), and a frequency corresponding to a single cycle of an input signal is represented by f(Hz). For example, ΔL=0.2 m is obtained in accordance with the equation, wherein a refractive index of each of the second optical fiber 202 and the third optical fiber 203 is set to be 1.5, a transmitting speed of an input signal is set to be 1 Gbps (a frequency is set to be 1 GHz), and c0=3×108 (m/s) is set.
The input signal takes a value of 0 or 1 in a predetermined signal cycle t (for example, 1 ns) as shown in
As shown in
Thus, the transmitting device 2 transmits a duo-binary signal obtained by converting an electric signal having a binary value of (0, 1) into an optical signal having a ternary value of (0, 1, 2) to the receiving device 3 through the optical transmitting path 4.
The optical transmitting path 4 is illustrative as a third optical transmitting medium according to the invention, and may be constituted by a single optical fiber or may be constituted by mutually coupling a plurality of optical fibers through an optical fiber coupler. Moreover, a relay amplifier may be provided between the optical fibers.
The receiving device 3 includes a photoelectric converting portion 31, an AD converting portion 32 and a decoding portion 33 as shown in
The photoelectric converting portion 31 converts the optical signal output from the optical transmitting path 4 into an electric signal, and amplifies and outputs the electric signal. The electric signal output from the photoelectric converting portion 31 has a signal level with a ternary value of (0, 1, 2) corresponding to the intensity of the optical signal transmitted through the optical transmitting path 4.
The AD converting portion 32 carries out an analog-digital conversion over the electric signal output from the photoelectric converting portion 31 and outputs a 2-bit signal. In other words, the AD converting portion 32 outputs a 2-bit signal having a high-order bit of one and a low-order bit of zero when the photoelectric converting portion 31 outputs a signal (2) having a high level. The AD converting portion 32 outputs a 2-bit signal having a high-order bit of zero and a low-order bit of one when the photoelectric converting portion 31 outputs a signal (1) having an intermediate level. Moreover, the AD converting portion 32 outputs a 2-bit signal having a high-order bit of zero and a low-order bit of zero when the photoelectric converting portion 31 outputs a signal (0) having a low level. The AD converting portion 32 outputs the 2-bit signal to the decoding portion 33.
The decoding portion 33 decodes a signal input to the input terminal 2a of the transmitting device 2 based on the 2-bit signal input from the AD converting portion 32 and outputs the decoded signal from the output terminal 3a.
An output of the OR circuit 335 is sent from the output terminal 3a to an outside and is input to a D input terminal of the D flip-flop circuit 336. Moreover, a clock signal having an identical cycle to a signal cycle of the signal input to the transmitting device 2 is sent from a clock signal generating circuit (not shown) to a clock input terminal of the D flip-flop circuit 336. Consequently, the
The decoding portion 33 thus executes the decode processing so that a decoding signal reproducing the signal input to the transmitting device 2 is sent from the output terminal 3a.
According to the transmitting/receiving device 1 having the structure described above, it is possible to generate a duo-binary signal based on the difference in the optical length between the second optical fiber 202 and the third optical fiber 203. For example, it is possible to carry out a transmission permitting an intersymbolic interference which might occur in an execution of a long-distance transmission.
Next, a second exemplary embodiment according to the invention will be described with reference to
The transmitting device 5 according to the exemplary embodiment includes an input terminal 5a, a first photoelectric converting portion 51 which is directly connected to the input terminal 5a, a second photoelectric converting portion 52 connected to the input terminal 5a through a delaying circuit 50, and an optical multiplexing portion 53 connected to a first optical fiber 501 connected to the first photoelectric converting portion 51 and a second optical fiber 502 connected to the second photoelectric converting portion 52. The first optical fiber 501 is illustrative as a first optical transmitting medium according to the invention. The second optical fiber 502 is illustrative as a second optical transmitting medium according to the invention.
The first photoelectric converting portion 51 accepts a signal input to the input terminal 5a without a delaying circuit, and outputs a light having a predetermined intensity to the first optical fiber 501 if the input signal is High(1). If the input signal is Low(0), moreover, the first photoelectric converting portion 51 does not cause a light source to emit a light and does not output the light to the first optical fiber 501.
The delaying circuit 50 serves to generate a delay corresponding to a single signal cycle of an electric signal input to the input terminal 5a. The delaying circuit 50 may be implemented by a flip-flop circuit which is synchronized with a cyclic signal (CLK), for example.
The second photoelectric converting portion 52 accepts the input signal delayed by the delaying circuit 50, and causes a light source such as a light-emitting diode to emit light and inputs, to the second optical fiber 502, a light having a predetermined intensity through the light emission if the signal is High(1). If the signal is Low(0), moreover, the second photoelectric converting portion 52 does not cause the light source to emit a light and does not input the light to the second optical fiber 502.
The first optical fiber 501 outputs, to the optical multiplexing portion 53, an optical signal input from the first photoelectric converting portion 51. Moreover, the second optical fiber 502 outputs, to the optical multiplexing portion 53, an optical signal input from the second photoelectric converting portion 52. It is assumed that the first optical fiber 501 and the second optical fiber 502 have optical lengths which are equal to each other.
The optical multiplexing portion 53 multiplexes a first optical signal input from the first optical fiber 501 and a second optical signal input from the second optical fiber 502, and generates a third optical signal obtained by adding intensities of the first and second optical signals. Furthermore, the optical multiplexing portion 53 outputs, to the optical transmitting path 4, the third optical signal thus generated as a transmitting signal.
The transmitting device 5 outputs the same transmitting signal as that in the transmitting device 1 described in the first exemplary embodiment. In other words, when the input signal shown in
Next, a third exemplary embodiment according to the invention will be described with reference to
The transmitting device 6 according to the exemplary embodiment includes an input terminal 6a, a first photoelectric converting portion 61 connected to the input terminal 6a, an optical branching portion 62 connected to the first photoelectric converting portion 61 through a first optical fiber 601, a photoelectric converting portion 63 connected to the optical branching portion 62 through a third optical fiber 603, a delaying circuit 64 connected to the photoelectric converting portion 63, a second photoelectric converting portion 65 connected to the delaying circuit 64, and an optical multiplexing portion 66 connected to the optical branching portion 62 through a second optical fiber 602 and connected to the second photoelectric converting portion 65 through a fourth optical fiber 604 respectively.
The second optical fiber 602 is illustrative as a first optical transmitting medium according to the invention. The fourth optical fiber 604 is illustrative as a second optical transmitting medium according to the invention.
The first photoelectric converting portion 61 accepts a signal input to the input terminal 6a, and outputs a light having a predetermined intensity to the first optical fiber 601 if the input signal is High(1). If the input signal is Low(0), moreover, the first photoelectric converting portion 61 does not cause a light source to emit a light and does not output the light to the first optical fiber 601. The first optical fiber 601 outputs, to the optical branching portion 62, the optical signal input from the first photoelectric converting portion 61.
The optical branching portion 62 branches the optical signal output from the first optical fiber 601 into the second optical fiber 602 and the third optical fiber 603 and outputs the branched optical signals. The optical signal input to the second optical fiber 602 is directly output to the optical multiplexing portion 66. The optical signal input to the third optical fiber 603 is output to the photoelectric converting portion 63.
The photoelectric converting portion 63 converts the optical signal output from the third optical fiber 603 into an electric signal, and outputs the electric signal to the delaying circuit 64. An output of the delaying circuit 64 is input to the second photoelectric converting portion 65. The second photoelectric converting portion 65 outputs the input electric signal to the optical multiplexing portion 66 through the fourth optical fiber 604.
A delay time of the delaying circuit 64 is set in such a manner that a delay corresponding to a single signal cycle of the input signal is generated in the second optical signal output from the fourth optical fiber 604 with respect to the first optical signal output from the second optical fiber 602. By setting a sum of optical lengths of the third optical fiber 603 and the fourth optical fiber 604 to be equal to an optical length of the second optical fiber 602, it is possible to set the delay time of the delaying circuit 64 corresponding to the signal cycle of the input signal.
The optical multiplexing portion 66 multiplexes the first optical signal input from the second optical fiber 602 and the second optical signal input from the fourth optical fiber 604 and generates a third optical signal obtained by adding intensities of the first and second optical signals. Moreover, the optical multiplexing portion 66 outputs, to the optical transmitting path 4, the third optical signal generated as a transmitting signal.
The transmitting device 6 outputs the same transmitting signal as that of the transmitting device 1 described in the first exemplary embodiment. In other words, in the case in which the input signal shown in
The invention is not restricted to each of the exemplary embodiments but various changes may be made without departing from the scope of the invention.
Although optical fibers having equal refractive indices are used for the second optical fiber 202 and the third optical fiber 203 to generate the delay of the optical signal depending on the difference between the lengths in the first exemplary embodiment, for example, the invention is not restricted thereto but a difference in an optical length (which is equal to a multiplication of an actual distance by a refractive index: an optical distance) may be made based on a difference in the refractive index between the second optical fiber 202 and the third optical fiber 203 or a difference in the refractive index and the length and the delay of the optical signal may be generated based on the difference.
Although the delay of the signal is generated by the delaying circuit 50 in the second exemplary embodiment, moreover, a delay of an optical signal corresponding to a single cycle may be generated by a combination of a delay made by the delaying circuit 50 and a delay based on the optical lengths of the first optical fiber 501 and the second optical fiber 502.
Although the delaying circuit 64 is provided in one of the two paths reaching the optical multiplexing portion 66 from the optical branching portion 62 in the third exemplary embodiment, furthermore, the invention is not restricted thereto but delaying circuits may be provided in both of the paths to generate a delay of an optical signal corresponding to a single cycle depending on a difference between delay times thereof.
The foregoing description of the exemplary embodiment of the present invention has been provided for the purpose of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and various will be apparent to practitioners skilled in the art. The embodiments were chosen and described in order to best explain the principles of the invention and its practical application, thereby enabling other skilled in the art to understand the invention for various embodiments and with the various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the following claims and their equivalents.
Number | Date | Country | Kind |
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2010-266386 | Nov 2010 | JP | national |