JPS6350193A - Optical switch matrix - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Field of Application) The present invention provides information transmitted using light as a medium! ,
This invention relates to an optical switch matrix which is a basic component of an optical switch exchanged in Section 4 and which has excellent crosstalk characteristics when the matrix is enlarged.

(Prior Art) Conventionally, as a method of configuring an optical switch matrix with M inputs and N outputs, optical path switching type optical switch elements with 2 inputs and 2 outputs are arranged at the intersections of an MXN matrix as shown in FIG. 3(a). ,
When the fork point is closed, the optical switch element is placed in the ar state as shown in FIG. 3(b), and when the fork point is not closed, the optical switch element is placed in the ERA! state as shown in FIG. 3(b). A configuration that realizes an MXN optical switch matrix by switching to the +3 state (non-blocking optical connection network using directional couplers) (H, S, HI
NTONr” A NonblockingInter
Connection Network Using
GLOB
ECOM '84.26.5.1 ] or Figure 4
As shown in (a), a gate type optical switch element is used to connect an optical branching device with 1 input and N outputs and an optical combiner with M inputs and 1 output, and f
There is a configuration that realizes an MXN optical switch matrix by switching an f-) type optical switch element between an on state and an off state as shown in FIG. IEICE General Conference, 517-1'l]. However, it is difficult to completely switch the cross/bar state of an optical path switching type optical switch element or the on10ff state of a gate type optical switch element, and when optical signals are present at multiple input terminals of an optical switch matrix, the output Crosstalk light appears at the terminal, but
In the configurations shown in FIGS. 3 and 4, crosstalk light from each input terminal is superimposed, and in the worst case, crosstalk light with an optical power approximately proportional to the number M of input terminals appears at the output terminal.

This will be shown below through calculations. First, in the case of the optical switch matrix shown in FIG. 3, the optical path switching type optical switch element cr
The signal-to-crosstalk ratio in the o8s state is assumed to be X (dB) as shown in FIG. 5(a). Further, the loss when an optical signal passes through the optical path switching type optical switch element is assumed to be L (dB). At this time, the worst value of the signal-to-crosstalk ratio at the output terminal is shown in Figure 5.
This is a case where the optical signal of the first input terminal is connected to the first output terminal as shown in (b), and the above-mentioned H, S, HI
From the NTON reference literature, it is given by equation (1).

(Worst value of signal vs. crosstalk) = X-(M-1) Ll-10
” In particular, in the case of loss → 0 (dB), that is, no loss, equation (1) is simplified as equation (2).

L-) 00 hours, formula (1) → x-101og (M-1)
(dB) (21 This is it) By forming optical path switching type optical switch elements into a matrix, the signal-to-crosstalk ratio is equal to the signal-to-crosstalk ratio in the case of a single element (X (dB)) 10t
It can be seen that it deteriorates by og(M-1) (dB).

Furthermore, it is easily shown that when the loss L>o(dB), the value of equation (1) is always smaller than the value of equation (2), that is, the signal-to-crosstalk ratio deteriorates.

On the other hand, in the case of the optical switch (IJ) shown in Fig. 4, if the ratio of the output optical signal light in the on state and the off state of the gate type optical switch element is K x (dB) as shown in Fig. 6(a), the output is The worst value of the signal-to-crosstalk ratio at the terminals is when optical signals exist at all input terminals as shown in FIG. 6(b), and is given by equation (3).

(Worst value of signal to crosstalk) =X-10tog(M-1)
(dB) (3) Equation (3) matches equation (2), but in this case it does not depend on the loss when the optical signal passes through the date type optical switch element.

(Problems to be Solved by the Invention) As described above, by forming the optical switch elements into a matrix in both the configurations of FIGS. Since the crosstalk light is directly superimposed, the signal-to-crosstalk ratio at the output terminal is 101° higher than the signal-to-crosstalk ratio X (dB) of the optical switch element alone.
g (M −1) (dB), and it is difficult to increase the scale M of the switch matrix.

An object of the present invention is to provide an optical switch matrix that is suitable for large-scale operation because the deterioration of the signal-to-crosstalk ratio at the output terminal is small and is approximately the same as the signal-to-crosstalk ratio of a single optical switch element. be.

(Means for Solving the Problems) The present invention provides an optical branching device with 1 input and N outputs (N is a natural number) provided corresponding to M input terminals (M=2m, m is a natural number).
When configuring an M input 1 output optical switch in an M input N output optical switch matrix in which M input 1 output optical switches provided corresponding to N output terminals are interconnected, (M-1) A number of 2-input 1-output optical switches are connected in Km stages in a tree structure to form an M-input 1-output optical switch.
Furthermore, each 2-input, 1-output optical switch is a 2-input, 1-output optical switch by connecting a gate-type optical switch element that turns the optical signal on and off to the input terminal of a 2-input, 1-output optical combiner. It is. As a result, crosstalk light is suppressed every time it passes through a 2-input 1-output optical switch connected in m stages, thereby realizing an optical switch matrix with excellent signal-to-crosstalk characteristics at the output terminals of the optical switch matrix.

(Example) FIG. 1(a) is a diagram showing the basic configuration of the present invention.

11 to IM are input terminals, 21 to 2M are 1-input and N-output optical splitters, 2ij (1 = 1 to N, j = 1 to M) are output terminals of the optical splitter, 31 to 3N are M inputs and 1 output. light switch,
3 j i (j = 1~M, i = 1~N)
are input terminals of the optical switch, and 41 to 4N are output terminals. Output terminal 2ij of optical splitter (t=t~N, j=1~M
) are the input terminals 3j of the optical switch with M input and 1 output, respectively.
Connect to i. Further, FIG. 1(b) is a diagram showing the configuration of the optical switches 31 to 3N with M inputs and 1 output.
=1 to m, j=1 to M/2) is the first stage counting from the left in the figure and the jth two-input one-output optical switch counting from the top. Moreover, FIG. 1(c) shows an optical switch 5 ij (i=1~m, j=1~M/2) with 2 inputs and 1 output.
6 is a diagram showing the configuration of a 2-input 1-output optical combiner;
71.72 is a date type optical switch element, 81.82 is 2
Input l is an input terminal of the output optical switch, and 9 is an output terminal. Optical signals input from input terminals 81 and 82 are turned on or off by gate-type optical switch elements 71 and 72, respectively. In the on state, the optical signal passes through the optical coupler 6 and is then output to the output terminal 9.

FIG. 2(a) is a diagram showing an example of the operation of the present invention, in which the number of input terminals M=4 and the number of output terminals N=4, one input terminal
1 to the output terminal 43, the optical signal from the input terminal 12 to the output terminal 41, and the optical signal from the input terminal 13 to the output terminal 42.
This is an example in which the optical signal at the input terminal 14 is output to the output terminal 44. Further, FIG. 2(b) is a diagram showing, as an example, the on state and off state of the date type optical switch element in the optical switch 31 of FIG. 2(a). As shown in the figure, the gate type optical switch element through which the optical signal passes is in the on state, and all other date type optical switch elements are in the off state.
It is in a state. In this way, an optical switch matrix is realized in which an optical signal from any input terminal can be outputted to any output terminal by appropriately switching the on state and off state of the gate type optical switch element. I understand.

(Effects of the Invention) The present invention improves the signal-to-crosstalk ratio at the output terminal compared to conventional optical switch matrix configurations. This will be shown below through calculations.

As mentioned in the section on the conventional optical switch matrix, the signal-to-crosstalk ratio X (dB) of the date-type optical switch element is
It is given in figure (b). That is, the gate type optical switch element is
Output optical signal/arm P in n state.

The signal-to-crosstalk ratio X (dB) is the crosstalk power PcO ratio in the off state expressed in decibels. For example, when the output optical signal power is 1 (watt), the crosstalk power PcO is 1010 ( Watt). Also, if the optical signal is f-
) type optical switch element or optical coupler with 2 inputs and 1 output does not affect the signal-to-crosstalk ratio, so here we proceed with the calculation assuming that there is no loss. next,
Consider the case where optical signals with a power of 1 (Watt) are input to all input terminals of an optical switch with M inputs and 1 output as shown in Figure 7, and the first optical signal among them is output to the output terminal. think of. The second to Mth optical signals appear as crosstalk noise at the output terminal. Although the case where the first input signal is outputted is taken as an example here, the results obtained are exactly the same even when the signals of the other input terminals are outputted. Since all the gate type optical switch elements through which the first input signal passes are in the on state, the power at the output terminal is 1 (watt). On the other hand, the second input signal indicates that the gate type optical switch element in the two-person car output optical switch 511 is in the OFF state, and thereafter 521 to 5
Since the gate type optical switch element at ml is in the on state, the crosstalk occurring at the output terminal is 1010 (watts). Further, the third input signal is obtained when the gate type optical switch elements in the two-person car output optical switches 512 and 521 are in the OFF state, and the gate-type optical switch elements in the subsequent two-person car output optical switches 531 to 5ml are in the ON state. For a certain reason, the power resulting in crosstalk at the output terminal is 1010 (watts). Similarly, since all the gate type optical switch elements from the two-person car output optical switches 51-1 to 5m1 are in the OFF state, the Mth input signal has a crosstalk power of 10- +o (watt). As described above, the total crosstalk power from the second to the Mth output terminals at the output terminal is -++...+(M/2)XIO10 (watts). Here, the signal-to-crosstalk ratio of the gated optical switch element is
If (d B) is thick to some extent and 10'0 (1 holds), equation (4) can be approximated by equation (5).

-5 (total of crosstalk/off) ≠ 1010 (watts) (5) Therefore, the first input signal is the sum of the signal light (watts) output to the output terminal and the crosstalk/!watts. The ratio is 15 (signal to crosstalk ratio) dust 10 log (1/1010) =
x (dB) (6).

Therefore, the signal-to-crosstalk ratio at the output terminal of the optical switch matrix according to the present invention is X (dB) from equation (6), and this value is nothing but the signal-to-crosstalk ratio of the gate type optical switch element alone. That is, in the conventional optical switch matrix, by forming the optical switch elements into a matrix, the signal-to-crosstalk ratio x (dB) of the optical switch element alone is Whereas the signal-to-crosstalk ratio deteriorated by 10 Log (M-1) (dB), the optical switch matrix according to the present invention does not suffer from such deterioration of the signal-to-crosstalk ratio.

As shown in the above calculations, the optical switch matrix IJ according to the present invention has excellent signal-to-crosstalk characteristics, relaxes the requirements for the signal-to-crosstalk characteristics of optical switch elements, and is suitable for large-scale matrices. It can be seen that

[Brief explanation of the drawing]

FIGS. 1(a) to (c) are diagrams showing the basic configuration of the present invention, FIGS. 2(a) to (b) are diagrams showing an example of the operation of the present invention, and FIGS. 3(a) to (b) 4(,)-(b) are diagrams showing the conventional configuration, FIG. 5(a)-(b) and FIG. 6(,).
-(b) are diagrams for calculating the signal-to-crosstalk ratio in the conventional configuration, and FIG. 7 is a diagram for calculating the signal-to-crosstalk ratio in the configuration according to the present invention. 11~IM...input terminal, 21~2N...1 input N
Output optical splitter, 211~2MN...1 input N output optical splitter output terminal, 31~3M...M input 1 output optical switch, 311~3NM...M input 1 output optical switch input terminal , 41~42-...output terminal, 511~5ml
...2 input 1 output optical switch, 6...2 input 1 output optical combiner, 71.72...date type optical switch element,
81.82...2 input 1 output optical switch input terminal,
9...Output terminal of a 2-input 1-output optical switch. Patent applicant/applicant Nippon Telegraph and Telephone Corporation Patent application agent Megumi Yamamoto - L1 diagram (cL) (b) 3 diagram (α) Cb) Loss 4, ""lp, (dB) Mark r 2 tv
丞5 Figure (Ql (b) Shin'J
't4&! NitoX = 101qe (dB) Hon Otsu side

Claims (1)

[Scope of Claims] M (M=2^m, m is a natural number) 1-input N-output (N is a natural number) optical branchers and N M-input 1-output optical switches are provided, and the 1-input Each output terminal of the N-output optical branching device is connected to the input terminal of a different M-input and 1-output optical switch, and each of the M-input and 1-output optical switch is connected to a 2-input and 1-output optical coupler and the two inputs. 2-input 1 configured by connecting a gate-type optical switch element to the two input terminals of a 1-output optical coupler
An optical switch matrix comprising m stages of output optical switches connected in series.