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| United States Patent |
6,614,950
|
|
Huang
, et al.
|
September 2, 2003
|
Fiber bragg grating-based optical CDMA encoder/decoder
Abstract
An optical spectral coding scheme for fiber-optic code-division
multiple-access (FO-CDMA) networks. The spectral coding is based on the
pseudo-orthogonality of FO-CDMA codes properly written in the fiber Bragg
grating (FBG) devices. For an incoming broadband optical signal, the
designed Bragg wavelengths of the FBG will be reflected and spectrally
coded with the written FO-CDMA address codes. Maximal-length sequence
codes (M-sequence codes) are chosen as the signature or address codes to
exemplify the coding and correlation processes in the FO-CDMA system. By
assigning the N cyclic shifts of an M-sequence code vector to N users, the
invention achieves an FO-CDMA network that can support N simultaneous
users. The FO-CDMA encoding/decoding devices consist of a series of FBGs.
To overcome the impact of multiple-access interference (MAI) on the
performance of the FO-CDMA system, the FBG decoder is configured on the
basis of orthogonal correlation functions of the nearly orthogonal
M-sequence codes.
| Inventors:
|
Huang; Jen-Fa (Tainan, TW);
Lo; Yu-Lung (Tainan, TW);
Hsu; Dar-Zu (Tainan, TW);
Hsieh; Chang-Yuan (Tainan, TW)
|
| Assignee:
|
National Science Council (Taipei, TW)
|
| Appl. No.:
|
848899 |
| Filed:
|
May 4, 2001 |
Foreign Application Priority Data
| Jun 23, 2000[CN] | 89112629 A |
| Current U.S. Class: |
385/15 |
| Intern'l Class: |
G02B 006/26; H04J 014/08 |
| Field of Search: |
385/14,15,37,24
359/124,127,130,136,137,173,188
|
References Cited [Referenced By]
U.S. Patent Documents
| 2001/0055138 | Dec., 2001 | Richardson et al. | 359/173.
|
| 2002/0063928 | May., 2002 | Hansen et al. | 359/130.
|
| 2002/0150334 | Oct., 2002 | Richardson et al. | 385/37.
|
Other References
K. O. Hill, et al; Fiber Bragg Grating Technology fundamentals and
Overview; Journal of Lightwave Technology, vol. 15. No. 8, Aug. 1997; (pp.
1263-125).
J.A. Salehi, et al; Coherent Ultrashort Light Pulse Code-Division Multiple
Access Communication Systems; Journal of Lightwave Technology, vol. 8, No.
3, Mar. 1990; (pp. 478-491).
Fan R.K. Chung, et al; Optical Orthogonal Codes: Design, Analysis, and
Applications; IEEE Transactions on Information Theory, vol. 35, No. 3, May
1989; (pp. 595-604).
L.R. Chen, et al; Applications of Ultrashort Pulse Propagation in Bragg
Gratings for Wavelength-Division Multiplexing and Code-Division Multiple
Access; IEEE Journal of Quantium electronics, vol. 34, No. 11, Nov. 1998;
(pp. 2117-2129).
M. Kavehrad, et al; Optical Code-Division-Multiplexed Systems Based on
Spectral Encoding of Noncoherent Sources; Journal of Lightwave Technology,
vol. 13, No. 3, Mar. 1995; (pp. 534-545).
R.A. Griffin, et al; Coherence Coding for Photonic Code-Division Multiple
Acess Networks; Journal of Lightwave Technology, vol. 13, No. 9, Sep.
1995; (pp. 1826-1837).
A. Grunnet-Jepsen, et al; Spectral Phase Encoding and Decoding Using Fiber
Bragg Gratings; Templex Technology; (undaated); (pp. PD33-1-PD33-3).
X. Wang, et al; Novel Temporal/Spectral Coding technique Based on Fiber
Brqgg Gratings for Fiber Optic CDMA Application; (undated); (pp.
WM50-1/341-343).
R. Papannareddy, et al; Performance Comparison of Coherent Ultrashort Light
Pulse and Incoherent Broad-Band CDMA Systems; IEEE Photonics Technology
Letters, vol. 11, No. 12, Dec. 1999; (pp. 1683-1685).
|
Primary Examiner: Sanghavi; Hemang
Attorney, Agent or Firm: Birch, Stewart, Kolasch & Birch, LLP
Claims
What is claimed is:
1. A system that includes an optical receiver decoder module for a FO-CDMA
network, the module comprising:
a matched set of cascaded fiber decoder gratings for spectral decoding the
received accumulated spectral chips by way of gratings disposed to reflect
a set of narrowband spectral chips at designated Bragg wavelengths and to
transmit a complementary set of spectral chips not at designated Bragg
wavelengths directly through the decoder gratings;
an optical circulator for circulating the accumulated spectral chips into
the matched set of cascaded fiber decoder gratings, and the reflected
optical signals to a de-correlated output branch;
a balanced photo-detector unit that includes a pair of identical
photodiodes that subtracts the transmitted complementary chips signal from
the reflected chips signal; and
an information data decision unit to read the net signal energy coming from
the balanced photo-detector to determine a received information data bit.
2. The system of claim 1, wherein
the fiber decoder gratings are configured on the basis of orthogonal
M-sequence codes such that a correlation subtraction is implemented on the
two identical photodiodes of the balanced photo-detector to eliminate the
possible multiple-access interference caused by other system users in the
FO-CDMA network.
3. The system of claim 1, further including an optical transmitter encoder
module for the FO-CDMA network, the encoder module comprising:
an incoherent optical source as optical carrier of external E/O modulated
information data, wherein the source is one of the following:
Edge-emitting LED's (ELEDs), Superluminescent Diodes (SLDs), and
Erbium-Amplified Spontaneous Emissions (Er-ASEs);
an external intensity modulator for "On-Off Keying" the optical intensity
of the incoherent light source with information data bits at the
transmitter end;
an optical circulator for circulating the modulated optical source signals
into fiber encoder gratings and the reflected spectral chips to the
encoded output branch; and
a set of cascaded fiber encoder gratings disposed to reflect sequences of
narrowband spectral chips at the designated Bragg wavelengths.
4. The system of claim 3, wherein
the transmitter encoder module is one of K spectrally pseudo-orthogonal
coded fiber grating encoders;
the receiver decoder module is one of K spectrally pseudo-orthogonal coded
fiber grating decoders;
the K transmitter encoder modules and K receiver decoder modules are
connected to each other with a K.times.K optical fiber star coupler;
the spectrum-encoded signals of transmitter encoder modules are put
together in the optical star coupler and broadcast to all receiver decoder
modules in the network; and
the information data bits are recovered using matched signature address
codes between encoder and decoder gratings.
5. The system of claim 4, wherein the fiber gratings are 0.8 cm to 2.0 cm
in length and the LED or Er-ASE source is of 45 nm to 53 nm in linewidth
so that either 7 different grating wavelengths can be designed to operate
at a data rate of 1.5 Gb/s or around 127 different grating wavelengths be
designed to operate at a data rate of 80 Mb/s and hence approximately 10.5
Gbps.user capacities can be provided for the claimed fiber-optic CDMA
network.
6. A FO-CDMA network that includes an optical transmitter encoder module
comprising:
an incoherent optical source as optical carrier of external E/O modulated
information data, wherein the source is one of the following:
Edge-emitting LED's (ELEDs), Superluminescent Diodes (SLDs), and
Erbium-Amplified Spontaneous Emissions (Er-ASEs);
an external intensity modulator for "On-Off Keying" the optical intensity
of the incoherent light source with information data bits at the
transmitter end;
an optical circulator for circulating the modulated optical source signals
into fiber encoder gratings and the reflected spectral chips to the
encoded output branch; and
a set of cascaded fiber encoder gratings disposed to reflect sequences of
narrowband spectral chips at designated Bragg wavelengths.
7. The network of claim 6, wherein
the transmitter encoder module includes a spectrally pseudo-orthogonal
coded fiber encoder grating device having a series of fiber Bragg gratings
to work as time domain spreaders as well as selective wavelength slicers;
the cascaded fiber Bragg gratings are designed with a spectral chips
pattern corresponding to the chips distribution of a nearly orthogonal
M-sequence codes;
the reflected chip wavelength is determined by the grating pitch and the
refractive index variation of the fiber Bragg gratings;
the incoming broadband optical signal having spectral components equal to
the designed Bragg wavelengths of the fiber gratings will cause the
spectral chip components to be reflected, and will cause the spectral chip
components not on the Bragg wavelengths to be transmitted.
8. The network of claim 7, further including: an optical receiver decoder
module comprising:
a matched set of cascaded fiber decoder gratings for spectral decoding the
received accumulated spectral chips by way of gratings disposed to reflect
narrowband spectral chips at the designated Bragg wavelengths and to
transmit complementary spectral chips not at the designated Bragg
wavelengths directly through the decoder gratings;
an optical circulator for circulating the accumulated spectral chips into
the matched set of cascaded fiber decoder gratings, and the reflected
optical signals to a de-correlated output branch;
a balanced photo-detector unit that includes a pair of identical
photodiodes that subtracts a transmitted complementary chips signal from
the reflected chips signal; and
an information data decision unit to read the net signal energy coming from
the balanced photo-detector to determine a received information data bit.
9. The network of claim 8, wherein
the receiver decoder module includes a spectrally pseudo-orthogonal coded
fiber decoder grating device having a series of fiber Bragg gratings;
the cascaded fiber decoder gratings are designed with a spectral chips
pattern corresponding to the chips distribution of the nearly orthogonal
M-sequence codes;
the decoder gratings characterize the same spectrum response as that of the
encoder gratings, but with a reversed grating order to accomplish the same
optical path for every component spectral chip;
the reflected and transmitted light fields from the Bragg decoder grating
devices complement each other and provide for information correlation
decoding.
10. The network of claim 9, wherein
the N code vectors from different cyclic shifts of any M-sequence codeword
of code length N are taken as signature address codes to provide for N
pairs of matched fiber encoder and decoder gratings; and
the quasi-orthogonal M-sequence coding arrangement greatly reduces
multiple-access interference from other simultaneous users and enhances
the user capacity of the FO-CDMA network system.
11. The network of claim 9, wherein the network employs a tunable fiber
grating encoder/decoder scheme controlled with piezoelectric transducer
(PZT) devices wherein
each of the receiver decoder gratings can tune on a particular incoming
signal by adjusting its address code to match the corresponding
transmitter encoder gratings; and
the Bragg wavelength of each fiber-grating decoder is adjusted
independently, effectively changing the signature spectral pattern and
allowing for programmable address codes for point-to-point communication
and point-to-multipoint networks.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
Not Applicable.
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT
Not Applicable.
FIELD OF THE INVENTION
This invention relates to an optical spectral coding scheme for a
high-performance optical code-division multiple-access (OCDMA) network
system. The encoder and decoder are structured with cascaded fiber Bragg
grating (FBG) devices. The scheme can eliminate the multiple-access
interference (MAI), and can promote the CDMA system capacity. Using the
simple coder structure and low cost devices, the invention can be used on
switching routers to connect local network computers, or on exchange
modules for signal switching between network nodes. It is applicable to
Asymmetric Digital Subscriber Loop (ADSL), or Cable Modem to connect with
digital home network, local area network (LAN), and Internet etc.
BACKGROUND OF THE INVENTION
Optical networking is one way to provide a range of telecommunications
services to meet the growing demands of an information-based society.
However, existing multiple access implementations for LAN (local-area
network) or MAN (metropolitan-area network) networks are apparently
inadequate. Optical code-division multiple-access (OCDMA) offers versatile
connection between numerous local network users, along with generous
control on the wavelength stability or network synchronization
requirements. Hence OCDMA techniques have drawn much attention in recent
years.
Fiber Bragg gratings (FBG) are produced by exposure of photosensitive fiber
to ultraviolet light. They have a refractive index that is spatially
periodic along the propagation axis of a fiber. The desirable filtering
characteristics of fiber Bragg gratings are disclosed by K. O. Hill and G.
Meltz (IEEE J. Lightwave Technology, vol. 15 (8), pp. 1263-1276, 1997) and
have been employed in some optical devices. For example, the Distributed
Bragg Reflector (DBR) is designed with Bragg gratings in the laser
resonant cavity. The DBR accumulates energy in the resonant cavity and
emits light when the accumulated energy reaches a threshold. Fiber
gratings have also been used for performing optical measurements. For
example, due to the Bragg wavelength's change with tension or temperature,
fiber Bragg gratings can measure the variation of external factors. In
addition, the gratings can be used for the gain compensation of an
Erbium-Doped Fiber Amplifier (EDFA), for the analyses improvement of
spectral analyzer, and so on.
In optical fiber communications, fiber Bragg gratings can be employed as
chromatic compensators. The propagation of long-wavelengths is slower than
the propagation of short-wavelengths, causing the phenomenon of pulse
broadening (or "dispersion") in fiber transmission. This pulse broadening
tends to reduce the data bit rate of digital communication. Fiber Bragg
gratings provide "chirped apodization" by reflecting long-wavelength
components at the front end of the grating and short-wavelength components
at the rear end of the grating. This compensates for chromatic dispersion
by ensuring that the full light band spends the same amount of time to
pass through chromatic dispersion and grating compensation. Another
popular application of FBG is the realization of light wave filter with
the desired wavelengths on the reflective end. Such characteristics of
fiber Bragg gratings are utilized in this invention to construct a new
scheme of optical CDMA encoder/decoder devices.
J. A. Salehi et al. disclosed the technology of code-division
multiple-access (CDMA) [IEEE J. Lightwave Technology, vol. 8 (3), pp.
478-491, 1990] for the application of optical fiber communications. In the
early periods, bipolar codes with good correlation properties, such as
M-sequence or Gold code, were adopted for the optical CDMA communications.
At the transmitter end, data bits are encoded into unipolar optical
signals. The receiver makes an Electrical/Optical (E/O) conversion and has
a bipolar address decoding procedure in the electrical domain. Since after
E/O conversions, the receiver must go through the procedure of Sequence
Inverse Keying (SIK), the system is named as the SIK-CDMA. The SIK-CDMA
system needs multiple electrical/optical and optical/electrical
conversions and hence has serious limitation on the data transmission
rate. Thereafter, research efforts have aimed at the all-optical signal
processing to promote the data transmission rate.
In the light wave domain, the optical signal is inherently a unipolar
system. As stated by F. R. K. Chung et al. [IEEE Trans. on Inform. Theory,
vol. 35 (3), pp. 595-604, 1989], unipolar signature code such as optical
orthogonal code (OOC) and modified prime code (MPC) can have the same
correlation characteristics as those of the traditional bipolar sequences.
Since the cross-correlation of unipolar codes is incapable of achieving
complete orthogonality, the number of "1" in code sequences must be
restricted to improve the correlation characteristic. Unfortunately, this
means that a given code sequence length should have relatively few "1".
The number of unipolar code sequences is therefore far less than that of
the traditional bipolar sequence codes.
One of the early demonstrations of OCDMA uses optical delay lines and
optical orthogonal codes for OCDMA time domain coding. The time-encoded
optical CDMA coder is as presented in FIG. 4. In this delay line
configuration of FIG. 4, the incoming signal is split into several
independent paths in which each signal is delayed according to the
specific delay elements of the desired optical orthogonal codes. The
tapped delay line scheme suffers from high splitting loss due to intensity
splitting among the optical delay lines. Also, to comply with the hasty
growth on the number of users, one needs to substantially lengthen the
code sequence to promote the system capacity. This increases system
expenditures and is unsuited for the economical benefit.
On retracing the past technology, there were cases on utilizing the concept
of optical phase coding to implement code-division multiplexing. These
technologies need coherent, ultrashort pulses, with transmitter and
receiver being wavelength and phase coherent. L. R. Chen et al.
investigated ultrashort pulse propagation in fiber Bragg gratings [IEEE
Journal of Quantum Electronics, vol. 34 (11), pp. 2117-2129, 1998] with
applications on Wavelength Division Multiplexing (WDM) and Code-Division
Multiple-Access (CDMA) systems. The adopted incident optical source is
broadband ultrashort pulse. The coding scheme is the table-lookup type of
frequency hopping. The decoder grating was arranged in a reverse order to
that of the encoder grating to accomplish the same optical path for every
component spectral chip.
A well-known frequency encoder for optical broadband sources is disclosed
in the article by M. Kavehrad and D. Zaccarin [IEEE J. Lightwave
Technology, vol. 13 (3), pp. 534-545, 1995], and is shown in FIG. 5. This
is the typical representative of incoherent broadband CDMA systems. The
optical frequency coder of FIG. 5 consists of a pair of diffraction
gratings placed at the focal planes of a unit magnification confocal lens
pair. The first grating spatially decomposes the spectral components
present in the incoming optical signal with a certain resolution. A
spatially patterned mask is inserted midway between the lenses at the
point where the optical spectral components experience maximal spatial
separation. After the mask, the spectral components are re-assembled by
the second lens and second grating into a single optical beam. The mask
can modify the frequency components in phase and/or in amplitude,
depending on the coherence property of the incident optical source. The
apparatus has been used with high-efficiency for temporal shaping of short
pulses. An example has been illustrated by R. A. Griffin et al. [IEEE J.
Lightwave Technology, vol. 13 (9), pp. 1826-1837, 1995] in an optical
coherence coding scheme to implement optical frequency hopping CDMA. This
article is the typical representative of coherent ultrashort pulse CDMA
systems.
Japan Pat. No. JP9312619A issued to Thomas Pfeiffer in 1997 brings up
another frequency-coding scheme of optical CDMA transmission system. By
virtue of a Fabry-Perot-like periodic optical filter, the LED or Er-ASE
source spectrum is divided into several narrow optical pulses, and then
processed with Electrical/Optical (E/O) data modulation. At the receiver,
an optical coupler makes Optical/Electrical (O/E) conversions on the
received accumulated optical pulses. The signals are then distributed to
different bandpass filters by a branching device. Each receiver has a
local oscillator to produce the necessary signals for data demodulation.
The electrical signal finally passes through the lowpass filter to
retrieve the desired data information. The encoding mechanisms in this
patent periodically sliced the optical source and then proceeded with the
optical modulation to achieve the coding effect.
A. Grunnet-Jepsen et al. incorporated phase shifts and wavelength chirps
among the grating segments and demonstrated coherent spectral phase coding
of pulses for use in CDMA systems [OFC/IOOC'99 conference proceeding, pp.
PD33/1-PD33/3, 1999]. X. Wang et al. used prime codes over FBGs to
demonstrate experimentally a novel hybrid temporal/spectral coding
technique for fiber optic CDMA application [OFC/IOOC'99 conference
proceeding, pp. PD34/1-PD34/3, 1999]. Both authors adopted ultrashort
pulses with coherent spectral coding scheme for simultaneous optical
pulses operation on the time and frequency domains.
R. Papannareddy and A. M. Weiner [IEEE Photonics Technology Letters, vol.
11 (12), pp. 1683-1685, 1999] evaluated performance comparisons between
coherent ultrashort pulse and incoherent broadband CDMA systems. Though
ultrashort pulse CDMA can in principle yield a substantial throughput
advantage over the incoherent broadband systems, incoherent threshold
energy detection is believed to be a more reliable approach than coherent
grating pulse alignment. Moreover, the scheme of coherent OCDMA needs
femto-second ultrashort pulse technology. This is still a great challenge
at the present time.
SUMMARY OF THE INVENTION
This invention discloses a "Fiber Bragg Grating-based Optical CDMA
Encoder/Decoder" scheme. It utilizes the fine filtering function of fiber
Bragg gratings to produce reflected and transmitted narrowband spectral
chips with specifically designed wavelengths. The invention combines the
precise filtering characteristics of optical fiber grating and the
pseudo-orthogonal correlations of maximal-length sequence codes
(M-sequence codes) to structure encoder/decoder modules for a fiber-optic
CDMA system.
The technology of optical CDMA allows multiple users in local area networks
(LAN's) to access the same fiber channel asynchronously with no delay or
scheduling. Multiple users within the same channel can simultaneously
deliver data messages and share the same wideband resources. The technique
of fiber-optic CDMA is a very good selection for developing optical fiber
as a broadband transmission medium. Code-division multiple-access system
possesses anti-interference characteristics and can solve the bursty
traffic problem. It enhances the system capacity and has good secrecy.
Hence it is proving desirable for wireless and fiber-optic communications.
To solve the deficiency that only unipolar sequence can be used on the
conventional optical CDMA system, this invention aims at using fiber Bragg
gratings to generate specific wavelength spectral chips. With the
pre-written M-sequence codes in the fiber gratings, the invention devises
a simple scheme for the fiber-optic CDMA encoder/decoder. With such a
scheme, traditional M-sequence codes can be suitably applied for the
optical fiber communications. The scheme can solve the deficiency that
unipolar sequence has to be largely lengthened to promote the number of
system users. More importantly, on utilizing the quasi-orthogonal
correlations of M-sequence codes, the invention can eliminate the
multiple-access interference (MAI) caused by other users in the system.
This greatly enhances the system performance and reduces the transmission
error probability.
On judging system performance under the same bandwidth and bit error
probability, coherent ultrashort pulse CDMA can in principle yield
substantial throughput advantage over the incoherent broadband CDMA.
However, coherent CDMA needs femto-second ultrashort pulse technology.
This is still a great challenge at the present time. This invention may be
used in non-coherent optical CDMA systems. The invention combines the
on-off keying modulation of broadband LED or Er-ASE sources and the
pseudo-orthogonal characteristic of M-sequence codes written in the fiber
gratings. The scheme can eliminate multiple-access interference (MAI)
encountered in optical CDMA systems. Unlike traditional OCDMA systems, the
present invention avoids the use of diffraction gratings, confocal lenses,
and/or optical phase masks. Instead, the invention devises properly coded
fiber grating devices to simplify system complexity The reliability of
fiber Bragg gratings is also dependable.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 illustrated system architecture of fiber-optic CDMA system;
FIG. 2 illustrated encoder scheme of fiber-optic CDMA system, (Encoder
module 10 taken as example);
FIG. 3 illustrated decoder scheme of fiber-optic CDMA system, (Decoder
module 30 taken as example);
FIG. 4 Optical coherence coding with tapped delay line known in the prior
art;
FIG. 5 Optical frequency coding with diffraction gratings, confocal lenses,
and phase mask known in the prior art.
FIGS. 6(a)-(c) Coder structures and spectrum responses of encoder gratings
102 and decoder gratings 302
FIG. 6(a) encoder gratings 102
FIG. 6(b) decoder gratings 302
FIG. 6(c) grating spectrum response
FIGS. 7(a)-(c) illustrated Er-ASE spectrum schema on encoder gratings 102
FIG. 7(a) source spectra before and after equalization
FIG. 7(b) spectrum response of grating
FIG. 7(c) reflected spectral chips
FIGS. 8(a)-(c) Coder structures and spectrum responses of encoder gratings
112 and decoder gratings 312
FIG. 8(a) encoder gratings 112
FIG. 8(b) decoder gratings 312
FIG. 8(c) grating spectrum response
FIGS. 9(a)-(c) illustrated LED spectrum schema on encoder gratings 112
FIG. 9(a) source spectra before and after equalization
FIG. 9(b) spectrum response of grating
FIG. 9(c) reflected spectral chips
FIGS. 10(a)-(c) spectrum schema of summed signal on decoder gratings 302
FIG. 10(a) received summed spectral chips
FIG. 10(b) reflected chips
FIG. 10(c) transmitted chips
FIGS. 11(a)-(c) spectrum schema of summed signal on decoder gratings 312
FIG. 11(a) received summed spectral chips
FIG. 11(b) reflected chips
FIG. 11(c) transmitted chips
REFERENCE NUMBER OF THE ATTACHED DRAWINGS
01.about.03 to be delivered message at the transmitter end
04.about.06 decoded message at the receiver end
10.about.12 optical encoder modules at the transmitter end
101 optical circulator in encoder module 10
102 multiple encoder gratings in the encoder module 10
112 multiple encoder gratings in the encoder module 10
103 external optical intensity modulator
104 Er-ASE optical source in the encoder module 10
114 LED optical source in the encoder module 11
105 input data stream for optical encoder module 10
106 encoded spectral signal from encoder module 10
115 input data stream for optical encoder module 11
116 encoded spectral signal from encoder module 11
20 K.times.K optical star coupler
21 K sets of transmitter encoder modules
22 input buffer module
23 K sets of receiver decoder modules
24 output buffer module
30.about.32 optical decoder modules at the receiver end
301 optical circulator in decoder module 30
302 multiple decoder gratings in the decoder module 30
312 multiple decoder gratings in the decoder module 31
303 balanced photo-detector unit within decoder module 30
313 balanced photo-detector unit within decoder module 31
304 information data decision unit
305 received summed spectral chips to decoder module 30
306 decoded information data bits from decoder module 30
315 received summed spectral chips to decoder module 31
316 decoded information data bits from decoder module 31
40 Er-ASE optical spectrum before equalization
41 spectrum response of fiber encoder grating 102
42 Er-ASE optical spectrum after equalization
421 reflected spectral chip at wavelength .lambda..sub.1
422 reflected spectral chip at wavelength .lambda..sub.2
423 reflected spectral chip at wavelength .lambda..sub.3
424 reflected spectral chip at wavelength .lambda..sub.6
50 LED optical spectrum before equalization
51 spectrum response of fiber encoder grating 112
52 LED optical spectrum after equalization
521 reflected spectral chip at wavelength .lambda..sub.2
522 reflected spectral chip at wavelength .lambda..sub.3
523 reflected spectral chip at wavelength .lambda..sub.4
524 reflected spectral chip at wavelength .lambda..sub.7
60 received summed spectral chips from star coupler 20
61 reflected spectral chips through fiber grating 302
62 transmitted spectral chips through fiber grating 302
611 reflected spectral chip at wavelength .lambda..sub.1
612 reflected spectral chip at wavelength .lambda..sub.2
613 reflected spectral chip at wavelength .lambda..sub.3
614 reflected spectral chip at wavelength .lambda..sub.6
621 transmitted spectral chip at wavelength .lambda..sub.4
622 transmitted spectral chip at wavelength .lambda..sub.5
623 transmitted spectral chip at wavelength .lambda..sub.7
70 received summed spectral chips from star coupler 20
71 reflected spectral chips through fiber grating 312
72 transmitted spectral chips through fiber grating 312
711 reflected spectral chip at wavelength .lambda..sub.2
712 reflected spectral chip at wavelength .mu..sub.3
713 reflected spectral chip at wavelength .lambda..sub.4
714 reflected spectral chip at wavelength .lambda..sub.7
721 transmitted spectral chip at wavelength .lambda..sub.1
722 transmitted spectral chip at wavelength .lambda..sub.5
723 transmitted spectral chip at wavelength .lambda..sub.6
DETAILED DESCRIPTION OF THE INVENTION
The invention of "fiber Bragg grating-based optical CDMA (code-division
multiple-access) encoder/decoder" consists of paired K transmitters and K
receivers that are connected in a star configuration to share the same
optical fiber medium. Each encoder and decoder is linked with a K.times.K
star coupler. Each bit of information from the corresponding user is
ON-OFF shift keying the broadband incoherent optical carrier to fulfill
the E/O modulation. The modulated optical field corresponding to each data
bit is directed to a fiber Bragg grating for the spectral encoding
operation. The spectrum-encoded lightwaves of each transmitter are put
together with an optical star coupler and broadcast to all receivers in
the network. At the receiver end, through the matched signature or address
codes, the transmitted signal sequence is reversed with successful
de-correlation process on the receiver decoder.
Optical code-division multiple-access (OCDMA) can elastically connect with
K network users, and can have generous control on the wavelength stability
or the requirement of network synchronism. Hence OCDMA techniques have
drawn much attention on multiple-access applications in local-area network
(LAN) or metropolitan-area network (MAN). This invention devises a
fiber-grating-based encoder and decoder scheme with applications on OCDMA
network system. The proposed OCDMA spectral coding devices consist of a
series of fiber Bragg gratings. The spectral pattern of fiber Bragg
gratings will correspond to the chips distribution of maximal-length
sequence codes (M-sequence codes) used for the optical encoding and
decoding of information data bits. The invention can eliminate
multiple-access interference (MAI) caused by other system users at the
receiver. In this way, it can enhance signal transmission quality and
promote the number of simultaneous users.
The invention aims at the spectral coding of incoherent lightwave signals
on the pseudo-orthogonal coded fiber Bragg gratings. By the phrase
"spectrally pseudo-orthogonal coded fiber Bragg gratings", we mean a
series of FBGs having the generated spectral chips patterns corresponding
to that of the nearly orthogonal CDMA codes. FIG. 1 illustrates the
proposed fiber-optic code-division multiple-access scheme. The system is
structured with a group set 21 of K transmitter encoder modules, a group
set 23 of K receiver decoder modules, and a K.times.K optical star coupler
20 used to link with encoders 21 and decoders 23. At the transmitter end,
delivered messages 01.about.03 pass through input buffer module 22 to
adjust the timing alignment of the optical encoders 21. At the receiver
end, decoded messages 04.about.06 pass through output buffer module 24 to
adjust the timing alignment of the optical decoders 23.
Optical transmitter encoders 21 comprises a set of K encoder modules
10.about.12. FIG. 2 illustrates the internal structure of the encoder
module 10. The encoder module 10 comprises an optical circulator 101, a
set of multiple fiber gratings 102, an external intensity modulator 103,
and an incoherent broadband optical source 104. Optical receiver decoders
23 comprises a set of K decoder modules 30.about.32. FIG. 3 illustrates
the internal structure of the decoder module 30. The decoder module 30
comprises an optical circulator 301, a set of multiple fiber gratings 302,
a balanced photo-detector unit 303, and an information data decision unit
304. This invention exemplifies the OCDMA system with K pairs of
simultaneous users. Each pair of users is assigned with the same set of
optical CDMA signature code. The encoder and decoder modules are linked
with a K.times.K star coupler. The network users access the same fiber
channel and share the same wideband resources.
The input buffer module 22 and output buffer module 24 illustrated in FIG.
1 are mainly used for timing alignment of users data bits in the
Electrical/Optical (E/O) and Optical/Electrical (O/E) processes. These
input and output buffer modules make easier the synchronization handling
among the asynchronous information data users. The proposed optical fiber
code-division multiple-access scheme can be applied both to point-to-point
communication and point-to-multipoint networks in which the receiver can
tune on a particular incoming signal by adjusting its address code to
match the corresponding transmitter. By use of piezoelectric transducer
(PZT) devices, the Bragg wavelength of each fiber-grating decoder may be
adjusted independently, effectively changing the signature spectral
pattern and therefore allowing for programmable address codes.
FIG. 2 illustrates the internal structure of optical transmitter encoder
module 10. The module comprises an optical circulator 101, a set of
multiple fiber gratings 102, an external intensity modulator 103, and an
incoherent broadband optical source 104. Suitable incoherent optical
sources for such encoder module include those of Edge-emitting LED's
(ELED), Superluminescent Diodes (SLD) and Erbium-Amplified Spontaneous
Emissions (Er-ASE). These sources offer broadband spectrum, high emitting
power, low temperature sensitivity, and small drive current requirement.
Particularly, the incoherent broadband sources are characterized by their
low costs due to high yields in packaging technology.
In the illustrated optical encoder module 10 shown in FIG. 2, information
data bit 105 from the corresponding user is On-Off Keying (OOK) the
incoherent broadband carrier 104 in the external intensity modulator 103
to fulfill the Electrical/Optical modulation. In other words, optical
energy will be transmitted for information bit "1" and an absence of
optical energy will signify information bit "0". The modulated optical
field corresponding to each data bit is directed through optical
circulator 101 to fiber encoder gratings 102 for spectral encoding. The
reflected spectral chips from fiber encoder gratings 102 are passed
through optical circulator 101 to become optical output signal 106. As
depicted in FIG. 1, the optical output signal 106 is directed to star
coupler 20 to couple with other reflected output signals from optical
encoder modules 11, 12. These spectrum-encoded lightwave signals are
summed or accumulated in the optical star coupler 20 and broadcast to all
the receivers in the network.
FIG. 3 illustrates the internal structure of optical receiver decoder
module 30. The module comprises an optical circulator 301, a set of
multiple fiber gratings 302, a balanced photo-detector unit 303 composed
with two identical photodiodes, and an information decision unit 304. For
data messages to be transmitted to the intended receiver, the optical
encoder grating 102 imposes a CDMA signature on information data bits.
This signature sequence, or generally called address code, must match to
that of the optical decoder grating 302 at the receiver end. The task of
the receiver is to extract the desired user's bit stream from the received
signal that consists of the desired data stream and the undesired
multiple-access interference (MAI). The capacity of optical CDMA network
is dependent on the ability of the decoder to cancel the multiple-access
interference. Such multiple-access interference is increased with the
number of users in the system.
In the illustrated optical decoder module 30 shown in FIG. 3, the
accumulated optical spectral chips 305 pass through optical circulator 301
and feed into decoder Bragg grating 302 to proceed spectrum decoding. The
spectral signals reflected from fiber decoder gratings 302 are output
through optical circulator 301. The reflected optical signal from decoder
gratings 302 is complement to the optical signal transmitted through
decoder gratings. These complementary spectral signals are incident on the
two photodiodes in the balanced photo-detector unit 303 for
optical-to-electrical photo-detection. The net energy of photo-detected
electrical current is read on the information decision unit 304. Within
one data bit, if the net energy of photo-detected electrical current is
high enough, the user data bit is decided as logical "1". On the contrary,
if the net energy of photo-detected electrical current is nearly zero, the
user data bit is decided as logical "0". The decoded output data bits 306
will finally depart the receiver decoder module 30 after passing through
the output buffer module 24, as depicted in FIG. 1.
The core element in the proposed fiber-optic CDMA encoder/decoder scheme is
fiber Bragg grating (FBG) devices. Fiber Bragg gratings are produced by
exposure of photosensitive fiber to ultraviolet light. They have a
refractive index that is spatially periodic along the propagation axis of
a fiber. The spectral chip wavelength is dependent on the grating pitch
and the refractive index variation of the FBGs. The spectral frequency
pattern of fiber encoder/decoder gratings, with spectral chips centered
about the Bragg wavelengths, is determined by the OCDMA codes properly
written in the fiber gratings. Maximal-length sequence codes (or simply
M-sequence codes) are used in this invention to exemplify the coding and
correlation processes among OCDMA network users. For M-sequence of code
length N, the N cycle shifts of any M-sequence codeword can be assigned to
N users to get an OCDMA network that can support N simultaneous users.
The fiber grating is simply an optical diffraction device where the
incoming wavelength matching the Bragg condition will be diffracted in the
opposite direction. This means that for an incoming broadband optical
signal having spectral component equal to the designed Bragg wavelength of
the fiber grating, the spectral chip component will be reflected, or it
will be transmitted. The gratings will spectrally and temporally slice an
incoming broadband spectrum to N component spectral chips with centered
wavelengths (.lambda..sub.1, .lambda..sub.2, . . . , .lambda..sub.N). Each
grating is designed to possess a given centered wavelength .lambda..sub.n,
1.ltoreq.n.ltoreq.N, that is different from others and is distributed over
the bandwidth of the chips. On employing a piezoelectric transducer (PZT)
device, the central wavelengths of FBGs can be adjusted independently,
effectively changing the signature spectral pattern and therefore allowing
for programmable address codes.
Since the optical spectra of incoherent Light-Emitting Diodes (LED) or
Erbium-Amplified Spontaneous Emissions (Er-ASE) sources are not uniform,
the reflected spectral chips from fiber Bragg gratings will have different
amplitudes. These different amplitudes of the chips will affect the
orthogonality of the code family. Theoretically, the chips can be designed
to be of different spectral widths to have equal optical chips power. In
reality, it is not easy to achieve diverse grating widths to balance the
flatness of optical source spectrum. It is impossible to achieve diverse
grating widths in the mass production of fiber gratings. As a compromised
way, the incoherent source can be suitably equalized, and the spectral
amplitude is equally sliced in the more flattened central region of the
equalized spectra. With such scheme of spectral equalization, every
spectral chip can have almost the same pulse energy. This strategy will
facilitate the receiver decoder design in view of signal energy detection.
With a properly written fiber-optic CDMA coding pattern, the reflected
light field from fiber Bragg grating will be spectrally encoded onto an
address code denoted by the code vector
X.sub.k =(x.sub.k,0, x.sub.k,1, . . . , x.sub.k,N-1)
or
##EQU1##
Here, N is the periodic length of the fiber-optic CDMA address code (or the
number of chips per bit). x.sub.k,n.epsilon.{0, 1}, for
0.ltoreq.n.ltoreq.N-1, is the n-th chip value of the k-th user's spectral
code. .LAMBDA..sub.c and p.sub.n (.lambda.) are the chip width and the
fundamental pulse of each chip in the spectral domain. The invention
assumes a Gaussian distribution for each fundamental chip pulse. Nearly
the same pulse energy for each spectral chip is also assumed.
A set of K.times.K passive star coupler 20 is used to connect the local
network users in the system. Each transmitter broadcasts its
spectrum-encoded signal to all the receivers in the network. The received
signal spectrum is a sum of all the active users' transmitted optical
signal spectra on star coupler 20:
##EQU2##
where b.sub.k.epsilon.{0, 1}, for k=1, 2, . . . , N, are the k-th user's
information data bits, and l.sub.k,
0.ltoreq.l.sub.k.ltoreq..LAMBDA..sub.c, is the k-th user's arbitrary shift
in spectral domain.
The receiver applies a correlating decoder to the incoming signal to
extract the desired bit stream. For simplicity, the invention assumes the
k-th user's arbitrary spectral shift to be l.sub.k =0, then the
correlating decoder output of the k-th user is
##EQU3##
The first term is the desired data stream of the k-th user, and the second
term is the multiple-access interference coming from the other users. In
order to reduce the influence of the MAI, the pseudo-orthogonal
multiple-access code sequence with low cross-correlation is necessary.
Pseudo-orthogonal codes with good correlation properties (i.e., high
auto-correlation peaks with low sidelobes, and low cross-correlation
functions) are needed to reduce the undesired interference from other
simultaneous network users. Such multiple-access interference (MA) is the
primary factor that limits the performance of the fiber-optic CDMA system.
To reduce the undesirable effects caused by MAI, orthogonal (or nearly
orthogonal) codes with acceptable levels of crosstalk between network
users are required. A distinguished FBG decoder scheme is configured on
the basis of the correlation functions of the nearly orthogonal M-sequence
codes. By etching M-sequence codes into the fiber gratings, the spectral
encoding and correlation decoding of fiber-optic CDMA system can be
implemented. With proper encoder/decoder design, an intended receiver user
that computes a well-defined correlation term will reject any interfering
user and obtain quasi- or pseudo-orthogonality among users in the OCDMA
system.
In the proposed fiber-optic CDMA system, each transmitter encoder is
assigned with an M-sequence signature code for optical spectral encoding.
The corresponding receiver decoder is assigned with the same M-sequence
address code for correlation decoding. Maximal-length sequence code is a
class of nearly orthogonal binary codes. The shift-and-add property of
M-sequences means that the modulo-2 sum of an M-sequence and any cycle
phase shift of the same M-sequence is another phase of the same sequence.
M-sequence code of length N=2.sup.n -1 contains (N+1)/2=2.sup.n-1 `1`s and
(N-1)/2=2.sup.n-1 -1 `0`s. That is, in each period of the sequence the
number of `1`s differs from the number of `0`s by one at the most. This is
the well-known pseudo-random characteristic of maximal-length sequence
codes.
Denote X=(x.sub.0, x.sub.1, . . . , x.sub.N-1) and Y=(y.sub.0, y.sub.1, . .
. , y.sub.N-1) to be two M-sequence code vectors of length N. The periodic
correlation between X and Y is defined as
##EQU4##
Note that only periodic correlation function is considered here; operations
of partial correlation or aperiodic correlation are not under
consideration. Let X=(x.sub.0, x.sub.1, . . . , x.sub.N-1) be the
complement code vector of X with chip elements obtained by x.sub.1
=1-x.sub.i. The periodic correlation between X and Y then is
##EQU5##
Our purpose is to construct a proper FBG encoder/decoder scheme that will
compute R.sub.XY (k)=R.sub.XY (k) in the fiber-optic CDMA network.
In the proposed fiber-optic CDMA system, M-sequence code vectors Y=T.sup.k
X can be assigned to different network users, where T.sup.k is an operator
that shifts M-sequence code vector X=(x.sub.0, x.sub.1, . . . , x.sub.N-2,
x.sub.N-1) cyclically to the right by k bits, 0.ltoreq.k.ltoreq.N-1. For
example, TX=(x.sub.N-1, x.sub.0, x.sub.1, . . . , x.sub.N-3, x.sub.N-2),
T.sup.2 X=(x.sub.N-2, x.sub.N-1, x.sub.0, . . . , x.sub.N-4, x.sub.N-3),
and T.sup.3 X=(x.sub.N-3, x.sub.N-2, x.sub.N-1, x.sub.0, . . . ,
x.sub.N-4), and so on.
Then, the periodic correlation between codes X and Y is
##EQU6##
Note that the sum i+k in the subscript of x.sub.i+k is taken modulo N.
According to the shift-and-add property of maximal-length sequence codes,
the invention can obtain the periodic correlation functions
R.sub.XY (k)=(N+1)/2, for k=0;
R.sub.XY (k)=(N+1)/4, for k=1 to N-1.
In the proposed fiber-optic CDMA system, the receiver that computes
correlation difference R.sub.XY (k)-R.sub.XY (k) will result in
##EQU7##
With respect to the above equation, the receiver decoder in the fiber-optic
CDMA network can be suitably designed by using the precise filtering
properties of the Fiber Bragg Gratings. Since maximal-length sequence
codes can achieve R.sub.XY (k)-R.sub.XY (k)=0 at the receiver end assigned
with signature X, the invention can construct two decoder branches based
on code vectors X and X to decode the received code vector Y. The receiver
user X that computes the correlation subtraction R.sub.XY (k)-R.sub.XY (k)
will get a null value. That is, an intended receiver user X with decoder
design based on the calculation of R.sub.XY (k)-R.sub.XY (k) will reject
the signal coming from the interfering user having sequence Y=T.sup.k X,
k.noteq.0. By assigning the N cycle shifts of an M-sequence codeword to N
users, the invention structures a network that can theoretically support N
simultaneous users without multiple-access interference. The invention has
therefore obtained quasi-orthogonality between the fiber-optic CDMA
network users.
The reflected chips pattern from FBG encoder/decoder is determined by the
signature address codes assigned to the transmitter/receiver users. In
order to reduce the effect of multiple-access interference in the
fiber-optic CDMA network, M-sequence codes with low cross-correlation
values are chosen as the signature address codes. An example is
illustrated in Table I for N=7 chips M-sequences address codes assigned to
the transmitter and receiver users.
TABLE I
assigned signature data transmitted
sequence bit optical signal
user#1 1 1 1 0 0 1 0 1 1 1 1 0 0 1 0
user#2 0 1 1 1 0 0 1 0 0 0 0 0 0 0 0
user#3 1 0 1 1 1 0 0 1 1 0 1 1 1 0 0
user#4 0 1 0 1 1 1 0 1 0 1 0 1 1 1 0
user#5 0 0 1 0 1 1 1 0 0 0 0 0 0 0 0
user#6 1 0 0 1 0 1 1 0 0 0 0 0 0 0 0
user#7 1 1 0 0 1 0 1 1 1 1 0 0 1 0 1
summed 3 3 2 2 3 2 1
spectral
chips (S)
Referring to Table I, user #1 is assigned the signature code X.sub.1 =(1,
1, 1, 0, 0, 1, 0). User #2 is assigned the signature code X.sub.2 =(0, 1,
1, 1, 0, 0, 1), which is one cyclic shift of the sequence X.sub.1. For
user #3, the assigned signature code is X.sub.3 =(1, 0, 1, 1, 1, 0, 0),
which is two cyclic shifts of the sequence X.sub.1. In this way, every
user will be assigned a unique N=7 chips M-sequence address code.
Among the assigned signature address codes in Table I, the `1`s represent
the spectral chips reflected from the corresponding gratings, and the `0`s
represent an absence of reflected spectral chips from the FBG coder. The
possible central wavelengths of the fiber Bragg gratings are designated as
the code vectors (.lambda..sub.1, .lambda..sub.2, .lambda..sub.3,
.lambda..sub.4, .lambda..sub.5, .lambda..sub.6, .lambda..sub.7). The FBG
coder for user #1 is assigned the signature X.sub.1 =(1, 1, 1, 0, 0, 1,
0). The corresponding fiber gratings are placed with central wavelengths
of .lambda..sub.1, .lambda..sub.2, .lambda..sub.3, and .lambda..sub.4,
while no grating wavelengths of .lambda..sub.4, .lambda..sub.5, and
.lambda..sub.7 are placed. Similarly, the FBG coder for user #2 is
assigned with the signature X.sub.2 =(0, 1, 1, 1, 0, 0, 1). The
corresponding fiber gratings are placed with central wavelengths of
.lambda..sub.2, .lambda..sub.3, .lambda..sub.4 and .lambda..sub.7, and no
grating wavelengths of .lambda..sub.1, .lambda..sub.5, and .lambda..sub.6
are placed. For user #3, with the assigned signature X.sub.3 =(1, 0, 1, 1,
1, 0, 0), the fiber gratings are placed with central wavelengths of
.lambda..sub.1, .lambda..sub.3, .lambda..sub.4 and .lambda..sub.5 and no
grating wavelengths of .lambda..sub.2, .lambda..sub.4 and .lambda..sub.7
are placed. Other users can be similarly placed their fiber grating
wavelengths according to their assigned signature sequences.
FIGS. 6(a)-(c) illustrate coder structures and spectrum responses of
transmitter encoder gratings 102 and receiver decoder gratings 302. The
spectrum responses are designed to correspond to the signature code
X.sub.1 =(1, 1, 1, 0, 0, 1, 0) assigned for user #1. The encoder/decoder
gratings are cascaded FBGs, each is of different central wavelength. The
multiple decoder gratings 302 (FIG. 6(b)) are arranged to an inverse
grating order with respect to the multiple encoder gratings 102 (FIG.
6(a)) to accomplish the same optical path for every component spectral
chip. The encoder gratings 102 and decoder gratings 302 characterize the
same spectrum response 41 (FIG. 6(c)).
FIGS. 7(a)-(c) illustrate the spectrum schema of Er-ASE optical source
signal 104 when it is incident upon fiber encoder gratings 102. FIG. 7(a)
contrasts the Er-ASE source spectrum 40 before equalization with the
Er-ASE source spectrum 42 after equalization. For the fiber encoder
gratings 102 with spectrum response 41 (FIG. 7(b)), a suitably equalized
Er-ASE source signal 42 can be sliced into several spectral chips (FIG.
7(c)). Each spectral chip has its individual central wavelength. For
example, the reflected spectral chip 421 at wavelength .lambda..sub.1, the
spectral chip 422 at wavelength .lambda..sub.2, the spectral chip 423 at
wavelength .lambda..sub.3, and the spectral chip 424 at wavelength
.lambda..sub.4. These spectral chips are designed to be of different
central wavelengths, but with nearly the same pulse energy. On view of
signal energy detection, this is convenient for OCDMA receiver to make its
data bits decoding.
FIGS. 8(a)-(c) illustrate coder structures and spectrum responses of
transmitter encoder gratings 112 and receiver decoder gratings 312. The
spectrum responses are designed to correspond to the signature code
X.sub.2 =(0, 1, 1, 1, 0, 0, 1) assigned for user #2. The encoder/decoder
gratings are cascaded FBGs, each is of different central wavelength. The
multiple decoder gratings 312 FIG. 8(b)) are arranged to an inverse
grating order with respect to the multiple encoder gratings 112 (FIG.
8(a)) to accomplish the same optical path for every component spectral
chip. The encoder gratings 112 and decoder gratings 312 characterize the
same spectrum response 51 (FIG. 8(c)).
FIGS. 9(a)-(c) illustrate the spectrum schema of LED optical source signal
114 when it is incident upon fiber encoder gratings 112. FIG. 9(a)
contrasts the LED source spectrum 50 before equalization with the LED
source spectrum 52 after equalization. For the fiber encoder gratings 112
with spectrum response 51 (FIG. 9(b)), a suitably equalized LED source
signal 52 can be sliced into several spectral chips (FIG. 9(c)). Each
spectral chip has its individual central wavelength. For example, the
reflected spectral chip 521 at wavelength .lambda..sub.2, the spectral
chip 522 at wavelength .lambda..sub.3, the spectral chip 523 at wavelength
.lambda..sub.4, and the spectral chip 524 at wavelength .lambda..sub.7.
These spectral chips are designed to be of different central wavelengths,
but with nearly the same pulse energy.
As illustrated in Table I, user #2, user #5 and user #6 are supposed to
transmit logical "0" information data bits, while the other users transmit
logical "1" information data bits. These information data bits will
synchronously on-off shift keying the incoherent LED or Er-ASE source. The
modulated broadband optical signals then feed into fiber encoder gratings
to proceed spectral domain encoding. The fiber gratings encoder is
introduced to control and modify the amplitude and/or phase spectra of the
broadband incoherent optical signals. For logical "0" data bits, the
encoded optical signal will be the all-zero spectral chips; for logical
"1" information bits, the encoded lightwave will be the corresponding
signature spectral chips. After fiber gratings encoder, the coded spectral
chips are combined in a 7.times.7 star coupler and broadcast to each
receiver in the network. Each receiver will receive the resultant code
vector S=(3, 3, 2, 2, 3, 2, 1), which is obtained by adding together each
transmitted chip sequence from every active user.
In the receiver, the address code assigned to the decoder will multiply the
incoming received signal to accomplish the correlation decoding process.
In order to spectrally decode the k-th user's information data, the
received code vector S is taken to multiply the decoder signature function
X.sub.k for correlation operation. The received accumulated spectral chips
are passed through the FBG decoder and split into reflected and
transmitted optical output fields. The correlation SX.sub.k is simply the
reflected light field of the FBG decoder. Since transmitted and reflected
light fields are complement to each other in the fiber grating devices,
the complement correlation SX.sub.k is the transmitted light field of the
FBG decoder. By using a pair of balanced photodiodes, the subtraction of
SX.sub.k -SX.sub.k can be implemented and then, through with information
data decision unit, the desired data bits stream can be obtained.
Table II, shown below, together with FIGS. 10(a)-(c) illustrate the
correlation decoding processes for user #1.
TABLE II
received(S) 3 3 2 2 3 2 1
sequence(X.sub.1) 1 1 1 0 0 1 0
reflected 3 3 2 0 0 2 0 10 unit
chips power
transmitted 0 0 0 2 3 0 1 6 unit
chips power
The FBG decoder for user #1 is assigned with the signature address code
X.sub.1 =(1, 1, 1, 0, 0, 1, 0). The spectrum response 41 of the fiber
decoder gratings 302 is as that shown in FIG. 6(c). When the received
summed spectral chips 60 (FIG. 10(a)) pass through Bragg decoder gratings
302, the signal is split into reflected and transmitted optical fields
that are complement to each other. In the reflected output field 61 shown
in FIG. 10(b), there are reflected spectral chip 611 at wavelength
.lambda..sub.1, the spectral chip 612 at wavelength .lambda..sub.2, the
spectral chip 613 at wavelength .lambda..sub.3, and the spectral chip 614
at wavelength .lambda..sub.4. In the transmitted output field 62 shown in
FIG. 10(c), there are transmitted spectral chip 621 at wavelength
.lambda..sub.4, the spectral chip 622 at wavelength .lambda..sub.5, and
the spectral chip 623 at wavelength .lambda..sub.7. The dotted curves in
FIGS. 10(a)-(c) refer to the possibly received maximal level of optical
signal energy within a data bit.
As illustrated in Table II, the summed spectra S=(3, 3, 2, 2, 3, 2, 1)
passed through the FBG decoder of address code X.sub.1 =(1, 1, 1, 0, 0, 1,
0) are split into reflected and transmitted spectral chips. The reflected
and the transmitted chip vectors are respectively SX.sub.1 =(3, 3, 2, 0,
0, 2, 0) and SX=(0, 0, 0, 2, 3, 0, 1). The reflected chip sequence is
added to be R.sub.SX.sub..sub.1 =.vertline.SX.sub.1.vertline.=10 units
power and the transmitted chip sequence is added to be R.sub.SX.sub..sub.1
=.vertline.SX.sub.1.vertline.=6 units power. With balanced
photo-detectors 303 within decoder module 30, the subtraction of these
spectrum power will result in R.sub.SX.sub..sub.1 -R.sub.SX.sub..sub.1
=4 units of photocurrent, corresponding to a detected logical data bit of
"1".
Table III, shown below, together with FIGS. 11(a)-(c) illustrate the
correlation decoding processes for user #2.
TABLE III
received(S) 3 3 2 2 3 2 1
sequence(X.sub.2) 0 1 1 1 0 0 1
reflected 0 3 2 2 0 0 1 8 unit
chips power
transmitted 3 0 0 0 3 2 0 8 unit
chips power
The FBG decoder for user #2 is assigned with the signature address code
X.sub.2 =(0, 1, 1, 1, 0, 0, 1). The spectrum response 51 of the fiber
decoder gratings 312 is as that shown in FIG. 8(c). When the received
summed spectral chips 70 (FIG. 11(a)) pass through Bragg decoder gratings
312, the signal is split into reflected and transmitted optical fields
that are complement to each other. In the reflected output field 71 shown
in FIG. 11(b), there are reflected spectral chip 711 at wavelength
.lambda..sub.2, the spectral chip 712 at wavelength .lambda..sub.3, the
spectral chip 713 at wavelength .lambda..sub.4, and the spectral chip 714
at wavelength .lambda..sub.7. In the transmitted output field 72 shown in
FIG. 11(c), there are transmitted spectral chip 721 at wavelength
.lambda..sub.1, the spectral chip 722 at wavelength .lambda..sub.5, and
the spectral chip 723 at wavelength .lambda..sub.6. The dotted curves in
FIGS. 11(a)-(c) refer to the possibly received maximal level of optical
signal energy within a data bit.
As illustrated in Table III, the summed spectra S=(3, 3, 2, 2, 3, 2, 1)
passed through the FBG decoder of address code X.sub.2 =(0, 1, 1, 1, 0, 0,
1) are split into reflected and transmitted spectral chips. The reflected
and the transmitted chip vectors are respectively SX.sub.2 =(0, 3, 2, 2,
0, 0, 1) and SX.sub.2 =(3, 0, 0, 0, 3, 2, 0). The reflected chip sequence
is added to be R.sub.SX.sub..sub.2 =.vertline.SX.sub.2.vertline.=8 units
power and the transmitted chip sequence is added to be R.sub.SX.sub..sub.1
=.vertline.SX.sub.2.vertline.=8 units power. With balanced
photo-detectors 313 within decoder module 31, the subtraction of these
spectrum power will result in R.sub.SX.sub..sub.2 -R.sub.SX.sub..sub.1
=0 units of photocurrent, corresponding to a detected logical data bit of
"0".
With the depicted fiber Bragg grating-based encoder/decoder scheme, the
invention assures every optical CDMA user to successfully receive
information data bits delivered from transmitter end. The invention is
capable of eliminating multiple-access interference caused by other system
users. Some practical limitations on the proposed fiber-optic CDMA
applications can be roughly discussed here. By the linewidth limitation of
incoherent optical sources, the number of coded grating chips is also
limited. Since the spectral linewidth of broadband optical sources is
limited, the linewidth has to be partitioned more thinly to support more
users in the system. In other words, narrower pulses have to be employed
to support the long length of M-sequence codes.
Assuming the fiber grating is of L=1.0 cm in length, the invention can
obtain a spectral chip width of .DELTA..lambda..sub.0.congruent.0.42 nm
for a nearly 100% reflectivity. The linewidth for incoherent LED or Er-ASE
sources is approximately 53 nm, so we can get about 127 (=53/0.42)
gratings for spectral chips coding. With M-sequences of code length 127 as
signature addresses, approximately 127 simultaneous users can be provided
for the proposed fiber-optic CDMA network. Practical number will be
slightly smaller if a guard band is taken into consideration.
The spectral encoder/decoders consist of sets of FBGs work as time domain
spreaders as well as selective wavelength slicers. The time domain spread
is not obvious for low data rate, but the round-trip transit time through
the cascaded fiber gratings needs to be considered. Typically, the length
of a fiber Bragg grating is about L=1.0 cm, and the light speed in the
fiber core is estimated to be v=c/n=2.055.times.10.sup.8 m/sec (the
refractivity of the fiber core is n=1.46). Suppose there are 7 users on
line (N=7 gratings cascaded), the maximum round-trip transit time is
derived to be T.sub.b =2NL/v=0.68 ns. In other words, the data rate can be
up to about R.sub.b =1/T.sub.b =1.5 Gb/s for 7 simultaneous users. If the
simultaneous users is increased to N=127, then the maximum round-trip
transit time will be T.sub.b =2NL/v=12.36 ns. In such case, the data rate
can be up to about R.sub.b =1/T.sub.b =80 Mb/s for 127 simultaneous users.
We believe that these figures are good enough to provide for today's
optical networking requirement.
Characteristics and Efficiencies
The invention aims at the successful applications of fiber Bragg gratings
(FBGs) and maximal-length sequence codes (M-sequence codes) in the encoder
and decoder devices of fiber-optic CDMA network system. On utilizing the
fine filtering characteristics of FBGs, narrowband spectral chips of
specific wavelengths can be produced to match the correlation
characteristics of the built-in M-sequence codes in the gratings.
Quasi-orthogonal correlations of M-sequence codes can suitably eliminate
the multiple-access interference caused by other system users. The
elimination of multiple-access interferences will greatly enhance the
performance of the fiber-optic CDMA network.
Though ultrashort pulse CDMA can in principle yield a substantial
throughput advantage over the incoherent broadband systems, incoherent
threshold energy detection is more reliable than coherent grating pulse
alignment. Moreover, the coherent OCDMA scheme needs femto-second
ultrashort pulse technology and this is still a great challenge at the
present time. The incoherent optical CDMA scheme combines the on-off
keying modulation of broadband optical sources and the build-in
pseudo-orthogonal characteristics of M-sequence codes. In such scheme, the
invention can eliminate multiple-access interference. The structure of the
fiber-optic CDMA encoder/decoder is simple and the system performance is
reliable.
The optical encoder/decoder devices comprises a series of fiber Bragg
gratings. The proposed FO-CDMA network can suitably eliminate the effects
of multiple-access interferences. This not only reduces the error
transmission rate but also promotes the whole system performance. On
reviewing the issued patents and research reports around the world, we
cannot find the same kind of OCDMA encoder/decoder devices with fiber
grating scheme. The adopted incoherent LED and Er-ASE sources offer
broadband spectrum, high emitting power, low temperature sensitivity, and
small drive current requirement. The architecture of fiber grating
encoder/decoders is quite simple and the system cost can be relatively
low.
The fiber-optic CDMA encoder/decoder modules can be applied in the
switching routers of local computer networks. They can work as signal
exchange unit of information networks between different data nodes. The
data nodes include the intelligent appliances of home security, cellular
phone, personal computers, high-definition televisions, and computerized
refrigerators, etc. Following the popularity of personal computer and
intelligent appliances, the invention can be applied in ADSL (Asymmetric
Digital Subscriber Loop) or Cable Modem to connect digital home network.
The invention can be applied on ITG (Internet Telephony Gateway) network.
Through with telephone and FAX services, an extension can link to
local-area network to turn into a network phone. The invention can also be
applied on FITL (fiber in the loop) between toll station and subscribers
to provide for broadband services of fiber-to-the-home (FTTH). Current
switching devices are mainly TDM (Time-Division Multiplexing), FDM
(frequency-Division Multiplexing) or WDM (Wavelength-Division
Multiplexing) schemes with limited network nodes connected. The invention
of FO-CDMA encoder/decoders can provide for 7 channels to access the
network at 1.5 Gbps data rate or 127 channels to access with 80 Mbps data
rate. These figures are good enough for today's optical networking
requirement.
* * * * *
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