4. Coded data generation or conversion
  5. Analog to or from digital conversion
  6. Using optical device,

Logic element employing saturable absorber

Coded data generation or conversion – Analog to or from digital conversion – Using optical device

Reexamination Certificate

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Details

C359S339000, C385S024000

Reexamination Certificate

active

06822591

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to all-optical OR and XOR logic elements, and more particularly, to all-optical OR and XOR logic elements employing saturable absorbers as optical gates.
2. Description of the Prior Art
Generally, a computing system is constructed by integrating gates such as AND, OR, XOR, NAND, NOR, NXOR, etc. Conventional computing systems have processed electrical signals using silicon-based devices. The conventional computing systems have restrictions on a processing speed and a capacity because needs for high speed and large capacity of the systems have been recently increased. To overcome the restrictions, a computing system having optical elements excellent in the processing speed or the capacity has been developed.
In particular, a number of researches and developments have been made on OR and XOR logic elements such as an XOR gate using an ultra-fast non-linear interferometer (UNI) disclosed in “20 Gbps All-optical XOR with UNI gate”, IEEE Photonic Technol., Vol. 12, pp. 834-836, (2000), by C. Bintjas et al., an XOR gate using a Sagnac gate disclosed in “10 GHz Boolean XOR with semiconductor optical amplifier fiber Sagnac gate”, CLEO, CThF5 (1999), by K. Zoiros et al., an OR gate using an interferometric wavelength converter disclosed in “10 Gbps All-optical logic OR in monolithically integrated interferometric wavelength converter”, Vol. 36, IEEE Electron. Lett., pp. 813-815 (2000), by T. Fjelde et al., an XOR gate disclosed in “Demonstration of 20 Gbps All-optical logic XOR in integrated SOA-based interferometric wavelength converter”, Vol. 36, pp. 1863-1864, (2000), by T. Fielde et al., and so forth.
Although the XOR gate using an ultra-fast nonlinear interferometer (UNI) and the XOR gate using a Sagnag gate have an advantage of high speed, they have also some disadvantages that it is difficult to adapt them to optical computing systems requiring a high degree of integration, due to the complexity of their essential elements consisting of optical fiber and the difficulty in integration with other elements.
Meanwhile, a semiconductor optical amplifier (SOA) uses a gain characteristic of semiconductor to amplify an input optical signal by its gain. Also, the semiconductor optical amplifier directly amplifies the optical signal without converting the optical signal into an electrical signal. Further, the semiconductor optical amplifier is constructed to have a structure similar to a semiconductor laser using compound semiconductor materials, and is subjected to a anti-reflecting thin film processing. For this reason, the semiconductor optical amplifier can amplify the optical signals by a high gain in a wide wavelength range in an optical communication system having wavelength band of 1.55 &mgr;m. Furthermore, the semiconductor optical amplifier has a smaller size than a conventional erbium-doped amplifier (EDFA) and can be monolithically integrated with other semiconductor optical elements and passive waveguides. Accordingly, the semiconductor optical amplifier is useful in various fields of applications such as a wavelength converter, an optical switch, a logic element, etc.
Now, the conventional all-optical OR and XOR logic elements using a semiconductor optical amplifier will be described with reference to
FIGS. 1A and 1B
.
The element shown in
FIG. 1A
includes first and second optical amplifiers
7
and
8
, a Y-combiner
4
, and a Y-branch
5
, whereas the element shown in
FIG. 1B
includes first and second optical amplifiers
17
and
18
, Y-combiners
14
a
,
14
b
and
15
b
, a Y-branch
15
a
and a filter
19
.
The logic element in
FIG. 1A
constitutes a Michelson interferometer, whereas the logic element in
FIG. 1B
constitutes a Mach-Zehnder interferometer. In the Michelson interferometer, a continuous-wave signal of &lgr;
cw
is splitted by a Y-branch
5
and then inputted to the first and second optical amplifiers
7
and
8
, respectively, whereas input optical signals of &lgr;s
1
and &lgr;s
2
are inputted to a first optical amplifier
7
. In this case, the surface to which the continuous-wave signal of &lgr;
cw
is provided with a anti-reflecting thin film
9
, while the surface to which the input optical signals of &lgr;s
1
and &lgr;s
2
is provided with a reflection facet
6
. It is known that if a surface is cleaved, that is, if a surface is not provided with the anti-reflecting thin film
9
, its reflectivity reaches about 30%.
The Mach-Zehnder interferometer in
FIG. 1B
is distinguished from the Michelson interferometer in
FIG. 1A
in that anti-reflecting thin film
16
a
and
16
b
are deposited on both surfaces. That is, the Michelson interferometer as well as the Mach-Zehnder interferometer makes use of a cross-phase modulation, and the two interferometers are similar to each other in that the phase of the continuous-wave signal is varied depending on the optical power of an input optical signal when a semiconductor optical amplifier is gain saturated. However, the two interferometers are different from each other in that in the Michelson interferometer, one surface is designed to be reflective so that the total length of the element is reduced to a half. That is, the size of the Mach-Zehnder interferometer can be reduced to a half using the reflecting surface because of its symmetrical configuration.
The interferometers described above make use of the phase difference of two paths. Therefore, non-linear materials such as an optical amplifier play an important role. Also, in order to obtain a sufficient phase shift by &pgr;, a variety of methods of, e.g. lengthening an optical amplifier, significantly increasing amount of input current to the optical amplifier, or significantly increasing an input optical power are used. Although lengthening an optical amplifier is the easiest way among them, the method is restricted to some extent since the total length of the element is increased with increase of the length of the optical amplifier. The length of the Michelson interferometer can be decreased to a half of the length of the Mach-Zehnder interferometer because it uses the reflecting surface as described above. That is, since the input optical signal is reflected and returns from the reflecting surface, the input optical signal passes through the optical amplifier twice. Nevertheless, since the input continuous-wave signal and the output logic signal are outputted from the same surface in the Michelson interferometer, an expensive device such as a circulator is additionally required to divide the two signals.
The conventional Mach-Zehnder interferometer type OR and XOR logic elements using the semiconductor optical amplifier uses a cross-phase modulation of the semiconductor optical amplifier. That is, the Mach-Zehnder interferometer takes advantage of the fact that the phase of the continuous-wave signal is varied depending on the optical power of the input optical signal in a state of the gain saturation of the semiconductor optical amplifier. When a cross-phase modulation is used, input current to each semiconductor optical amplifier is differentiated to increase the phase difference between the paths A and B.
Therefore, conventionally, since phase of the continuous-wave signal is varied depending on the intensity of the input optical signal and a desired operational characteristic can be obtained only in a specific range of the intensity of the input optical signal and only with a specific input current to the semiconductor optical amplifier (SOA), an operational range was very restrictive.
SUMMARY OF THE INVENTION
It is an object of the present invention to alleviate a restriction on the operational input power dynamic range by making no phase difference between paths be generated depending upon the variation of an input optical power, unlike the cross-phase modulation type logic element using a semiconductor optical amplifier.
Another object of the present invention is to provide a logic element having available advantages such as elimination of noises and increa

Kim Hyun Soo

Inventor

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Kim Jong Hoi

Inventor

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Kim Kang Ho

Inventor

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Kwon Oh Kee

Inventor

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Oh Kwang Ryong

Inventor

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Blakely & Sokoloff, Taylor & Zafman

Law Firm

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Electronics and Telecommunications Research Institute

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Nguyen John B

Examiner

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