JPH0614324A - Picture transmission system - Google Patents

Abstract

PURPOSE:To provide a picture transmission system for directly transmitting two-dimensional picture information as a two-dimensional optical signal without generating distortion. CONSTITUTION:An optical beam obtained by the spatial Fourier transformation of a fiber output 1-13 of reference light sent from the receiving side by a prescribed polarized wave, an optical beam obtained by the spatial Fourier transformation of light obtained by previously passing an image optical signal to be transmitted through an optical fiber 1-8 similar to an extremely short transmitting optical fiber and a plane wave 1-11 applied from the reverse direction opposed to the transmission signal are made incident upon a non-linear optical medium 1-4 for generating a phase conjugate wave from the transmitting side and the phase conjugate wave advancing against the direction of the reference optical beam is generated and propagated to the receiving side through an optical fiber 1-3, so that a picture free from distortion can be obtained on the receiving side and image transmission having no distortion can be attained through a multimode optical fiber.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image transmission system for directly transmitting two-dimensional image information as a two-dimensional optical signal by utilizing optical parallelism and high speed in the communication field. is there.

[0002]

2. Description of the Related Art When transmitting image information, it is possible to communicate at higher speed by directly transmitting a two-dimensional signal as it is, rather than converting the image information into a time series signal such as a video signal and transmitting it. There is a nature. Therefore, conventionally, some image direct transmission methods using a multimode optical fiber (hereinafter referred to as a multimode optical fiber) have been proposed.

FIG. 2 is a conceptual diagram of a first conventional example of an image direct transmission system using a multimode optical fiber. Figure 2
In the above configuration, the light image generated from the transmission image 2-1 is reduced by the condenser lens 2-2 and is incident on the first multimode optical fiber 2-3 having the length L, and Excite each guided mode. At this time, each excited waveguide mode propagates in the multimode optical fiber 2-3 with different propagation constants. The mode propagation constant of the optical fiber 2-3 differs for each mode (this is called mode dispersion).
Therefore, a phase difference occurs between propagating modes, and a phase distortion occurs in the image.

An image propagated through a fiber and having a phase distortion is incident on a phase conjugate wave generator 2-5. The phase conjugate wave of the incident light generated here is made incident on the multimode optical fiber 2-4 having the length L having the same mode dispersion characteristics as the optical fiber 2-3. When the incident phase conjugate wave propagates through the optical fiber 2-4, it undergoes a phase change equal to the amount of mode dispersion of the optical fiber 2-3. Therefore, by propagating the optical fiber 2-4 by a length L, phase distortion occurs. Are canceled out, and a reproduced image 2-6 without distortion is obtained.

FIG. 3 is a conceptual diagram of a second conventional example of the image direct transmission system using the same multimode optical fiber. The image of the light generated from the transmission image 3-1 is reduced by the condenser lens 3-2, and the multimode optical fiber 3-3 is used.
And excites each guided mode of the optical fiber. At this time, the image undergoes phase distortion due to the mode dispersion of the optical fiber. This distorted image is spatially Fourier transformed by the Fourier transform device 3-4 to spatially separate the modes. Then, after entering into a hologram element 3-5 prepared in advance by a method described later to remove phase distortion due to mode dispersion, an inverse Fourier transform is performed by an inverse Fourier transform device 3-6, thereby reproducing an image almost equal to the original image. Images 3-7 are obtained.

FIG. 4 shows a method of manufacturing the hologram element shown in FIG. First, light is incident from the left end of the multimode optical fiber 4-1 to uniformly excite all guided modes of the optical fiber 4-1. The light beam ow obtained by spatially Fourier transforming the outgoing light from the optical fiber 4-1 by the Fourier transform device 4-2 and the reference light rw at different angles.
-3, and the interference fringes of both beams are recorded as a hologram, thereby producing the hologram element 3-4.

FIG. 5 is a conceptual diagram of a third prior art example of an image direct transmission system which also uses a multimode optical fiber. On the transmission side, the input image signal light 5-11 obtained from the transmission image 5-10 and the reference light 5-1 of the polarization orthogonal to this
2 and 2 are multiplexed by the multiplexer 5-1 and are simultaneously incident on the multimode optical fiber 5-2, and the image signal light and the reference light emitted from the multimode optical fiber 5-2 on the receiving side are separated. After being separated by the wave unit 5-3 and spatially Fourier-transformed by the first and second Fourier transform units 5-4 and 5-5, respectively, the two beams are both sent to the phase conjugate wave generator 5-6. The input signal is generated, a phase conjugate wave of the image signal light is generated, this is converted into a predetermined pattern by the T converter 5-7, and then inverse Fourier transform is performed by the inverse Fourier transform device 5-8 to obtain a reproduced image 5-9. I will get it.

[0008]

In the first prior art example described above, two multimode optical fibers having exactly the same mode dispersion characteristics are required to restore a completely distortion-free image. However, this is practically impossible,
In reality, some of the distortion remains, so it is difficult to obtain an image with no distortion.

In the second conventional example, the mode dispersion characteristics of the optical fiber may change due to changes in the environment in which the optical fiber is placed and other external factors. In such cases, image distortion cannot be completely compensated.

Further, in the third conventional example, the image signal light and the reference light must be propagated in the optical fiber with polarized waves orthogonal to each other. For that purpose, it is necessary to use a polarization-maintaining fiber having a function of keeping the polarization direction constant, but in that case, degeneration of two orthogonal polarization modes is solved, and the propagation constants are different from each other. Complete compensation is impossible in principle.

The present invention has been made in view of the above circumstances, and an object thereof is not to require two multimode optical fibers having exactly the same mode dispersion characteristics, and the mode dispersion characteristics of the optical fiber can be time-dependent due to external factors. It is an object of the present invention to provide an image transmission method capable of compensating for distortion in real time by following the change even when the change occurs in a dynamic manner.

[0012]

In order to solve the above-mentioned problems, the present invention is an image transmission system for transmitting two-dimensional image information using a multimode optical fiber. A light beam obtained by spatially Fourier transforming the fiber output of the reference light, and a light beam obtained by spatially Fourier transforming the image optical signal to be transmitted through a very short transmission optical fiber and the same kind of optical fiber. And a plane wave from the opposite direction opposite to the transmission signal is made incident on a nonlinear optical medium that generates a phase conjugate wave on the transmission side to generate a phase conjugate wave that travels backward in the direction of the reference light beam. It was made to propagate through the fiber to the receiving side.

[0013]

According to the present invention, the phase distortion due to the mode dispersion of the multimode optical fiber used as the transmission line is sent from the receiving side to the reference light in advance, and the reference light, the input signal light to be transmitted and the pump light are transmitted. Are mixed by four light waves in a nonlinear optical medium to generate a phase conjugate wave. The generated phase conjugate wave has a form in which the image information to be transmitted is superimposed on the phase distortion of the optical fiber, and by transmitting this,
Since the phase distortion due to the mode dispersion of the optical fiber can be compensated, an image without distortion can be obtained on the receiving side in principle, and the distortion-free image transmission using the multimode optical fiber can be realized.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a conceptual diagram showing an embodiment of an image transmission system according to the present invention. 1-1 is a transmitter, 1-2 is a receiver, 1-3 is a multimode optical fiber transmission line, 1-4 is a phase conjugate wave generator, 1-5 is a spatial Fourier transform unit, 1-
6 is a pattern conversion unit, 1-7 is a reference light signal transmitter, 1
-8 is a mode generation unit for converting an image into a guided mode of an optical fiber, 1-9 is an input image, 1-10 is an output image, 1-
Reference numeral 11 is a pump light beam, 1-12 is a transmitted reference optical signal, and 1-13 is a transmitted reference optical signal.

First, prior to transmitting an image, the receiving unit 1-
The reference optical signal 1-12 generated by the transmitter 1-7 from 2 is sent to the transmitter 1-1 through the optical fiber transmission path 1-3. In the transmitter 1-1, the transmitted reference optical signal 1-
The spatial Fourier transform unit 1-5 performs a spatial Fourier transform on 13 and inputs the same to the phase conjugate wave generation unit 1-4 of the transmission unit 1-1 together with the pump light beam 1-11. On the other hand, the image optical signal generated from the input image excites the guided mode of the optical fiber in the mode generation unit 1-8, and this is spatially Fourier transformed in the spatial Fourier transform unit 1-5, and the phase conjugate wave is also generated. Input to the section 1-4. At this time, the reference light signal beam 1-13 and the pump light beam 1-11 are incident facing each other. The polarizations of the pump light beam 1-11 and the image light signal beam 1-8 are the same as the polarization of the reference light signal 1-12. The phase conjugate wave generated by the phase conjugate wave generation unit 1-4 is returned to the original image by the pattern conversion unit 1-6, and then transmitted from the transmission unit 1-1 toward the reception unit 1-2 through the optical fiber transmission line. Sent through 1-3.

Here, the principle of returning the transmitted image to an original image without phase distortion by using the above-mentioned phase conjugate wave will be described. The Z axis is taken in the optical axis direction of the multimode optical fiber, the incident end is Z = 0, and the emitting end is Z = L. Now 2
When entering the original image p dimension to an optical fiber, the incident end image is expressed by p = ΣA _m e _m as a superposition of the field distribution e _m of the waveguide mode of the optical fiber. When this propagates in the optical fiber, p ′ = ΣA _{m m} e _m exp (−jβ _m L) at the output end, and the term of exp () is added as phase distortion. Here, β _m is the propagation constant of the m-th guided mode.

On the other hand, the above-mentioned phase conjugate wave is represented by p ″ = ΣA _{m m} e _m exp (+ jβ _m L). Therefore, when this phase conjugate wave propagates through the optical fiber of length L, the phase item is just Since they are canceled and become p = ΣA _m e _m , the distortions cancel each other out at the exit end, and the original image is restored. In this example, assuming that the wavelengths of the signal light, the reference light and the pump light are all the same, the phase conjugate wave is generated by the degenerate four-wave mixing. Four-wave mixing is
The source is a non-linear polarization generated by the signal light beam and the plane wave acting as the reference light and the pump light interfering with each other in the non-linear optical medium. It is a phenomenon.

A photorefractive crystal is used as the nonlinear optical medium used here. Photorefractive crystals include paraelectric materials such as BSO and BaT.
Ferroelectric materials such as iO ₃ and SBN, and also semi-insulating Ga
There are compound semiconductors such as As.

Next, an example of the optical configuration of the transmitting unit 1-1 in FIG. 1 will be described in detail. FIG. 6 shows an optical system of the transmitter, 6-1 is a photorefractive crystal for generating a phase conjugate wave, 6-2 is a Fourier transform lens, 6-3.
Is a pattern converter, and 6-4 is a mode converter for converting an image into a waveguide of an optical fiber. Normally, a very short multimode optical fiber similar to that used for a transmission line is used. 6-5 is a condenser lens, and 6-6 is a mirror.

Light 6-7 that has passed through the pattern of the input image
Is incident on the mode converter 6-4 by the lens 6-5, is Fourier transformed by the lens 6-2, and is incident on the photorefractive crystal 6-1. Reference numeral 6-8 is a plane wave used as pump light, and is incident on the photorefractive crystal 6-1 together with light 6-9 obtained by Fourier transforming the reference light transmitted from the receiving side. The signal light 6-10 to be transmitted is the phase conjugate wave generated by the degenerate four-wave mixing in the photorefractive crystal 6-1 and is subjected to pattern conversion by the pattern converter 6-3 and then by the Fourier transform lens 6-2. It is obtained by inverse Fourier transform. Due to the law of conservation of momentum, the direction of the phase conjugate wave is generated in the direction opposite to that of the reference light.

Here, the pattern converter 6-3 corrects the spatial amplitude and phase based on the conditions defined by the specifications of the multimode optical fiber used. The transmittance T _m of the pattern converter for the m-th order guided mode is
It is given by the following formula.

The ^{_{T m = | E m | 2}} / E m where, E _m is the spatial Fourier transform of the electric field distribution e _m of m-th order guided mode. This pattern can be easily created by a computer generated hologram.

[0023]

As described above, according to the present invention, it is possible to perform image transmission at a higher speed by the number of pixels, as compared with the conventional method of sequentially transmitting pixel by pixel. Since this effect becomes remarkable as the number of pixels increases, it will become more and more remarkable as the needs for high-definition images increase with the spread of HDTV in the future. Further, in the present invention, since the image is transmitted using the reference light transmitted from the receiving side, it can be used for interactive image communication.

[Brief description of drawings]

FIG. 1 is a conceptual diagram showing an embodiment of an image transmission system according to the present invention.

FIG. 2 is a conceptual diagram of a first conventional example of an image direct transmission system using a multimode optical fiber.

FIG. 3 is a conceptual diagram of a second conventional example of an image direct transmission system using a multimode optical fiber.

FIG. 4 is an explanatory diagram of a hologram creating method.

FIG. 5 is a conceptual diagram of a third conventional example of an image direct transmission system using a multimode optical fiber.

FIG. 6 is a detailed explanatory diagram of a transmission unit.

[Explanation of symbols]

1-1 ... Transmission unit, 1-2 ... Reception unit, 1-3 ... Multimode optical fiber transmission line, 1-4 ... Phase conjugate wave generation unit, 1-
5 ... Spatial Fourier transform unit, 1-6 ... Pattern transform unit, 1
-7 ... Transmitter for reference light signal, 1-8 ... Mode generator, 1
-9 ... Input image, 1-10 ... Output image, 1-11 ... Pump light beam, 1-12 ... Transmitted reference light signal, 1-1
3 ... Transmitted reference light signal.

Claims (2)

[Claims] 1. An image transmission system for transmitting two-dimensional image information using a multi-mode optical fiber, which is a light beam obtained by spatially Fourier-transforming the fiber output of reference light sent with a predetermined polarization from the receiving side. And a light beam obtained by spatially Fourier transforming the image optical signal to be transmitted through an optical fiber of the same kind as an extremely short transmission optical fiber in advance, and a plane wave from the opposite direction facing the transmission signal. ,
An image transmission method characterized in that a phase conjugate wave that travels backward in the direction of the reference light beam is generated by making it enter a nonlinear optical medium that generates a phase conjugate wave on the transmission side, and propagates to the reception side through an optical fiber. . 2. The phase conjugate wave generated by the above method is subjected to spatial amplitude and phase correction based on conditions defined by the multimode optical fiber. Image transmission method.