Optical waveguides – With optical coupler – Switch
Reexamination Certificate
2001-08-07
2003-12-02
Nguyen, Khiem (Department: 2839)
Optical waveguides
With optical coupler
Switch
C385S024000
Reexamination Certificate
active
06658175
ABSTRACT:
The invention relates to a switch for optical signals and more particularly to a switch for packet signals.
Telecommunications are expanding considerably. More and more users (individuals and businesses) are transmitting an increasing number of messages in telecommunication networks. Also, the messages include an ever-increasing quantity of information, for example when sending pictures. To respond to this growing demand for information bit rate, telecommunications network operators are using optical signal transmission, which modulates optical signals, generally produced by lasers, in accordance with the information to be transmitted, after which the modulated signals propagate in a network of conductors or optical fibers.
Transmitting signals optically has several advantages. In particular, the attenuation of the signal during transmission is less than in the case of electrical signals and the bandwidth of optical fibers is greater. It is therefore possible to transmit several carriers with different wavelengths simultaneously in the same fiber. This technique, known as wavelength division multiplexing, achieves information bit rates of the order of 1 terabit/s.
In parallel with wavelength division multiplexing, time division multiplexing enables simultaneous transmission of several calls on the same carrier. In packet mode, each carrier transmits packets relating to different messages whose information has been divided up into packets, each packet being launched into the network with a header indicating its destination. When the packet passes through a switching device, the device dedicates resources to routing the packet during the time period needed to switch the packet to a requested output. Those resources are then freed again for switching another packet. Because the packets are of limited duration, of the order of 1 microsecond, many calls can be transmitted in a short time period. This routing policy is currently used on the largest of all networks: the Internet.
Implementing switches using optical technology has been envisaged. Two types of switch can be distinguished:
cross-connect switches that set up semi-permanent connections between trunks routing a large number of multiplexed messages or calls, and
switches capable of routing calls or messages individually, i.e. that can be reconfigured for each new call or each new message.
The document JINNO M ET AL.: “ULTRA-WIDE-BAND WDM NETWORKS AND SUPPORTING TECHNOLOGIES” CORE NETWORKS AND NETWORK MANAGEMENT, AMSTERDAM: IOS PRESS, NL, 1999, pages 90-97, XP000829416 ISBN/90-5199-497-4 describes a cross-connect switch that receives and switches, without demultiplexing them, optical signals consisting of 16 carriers having different wavelengths. This switch cannot route individual calls or messages. Also, it is designed for very low switching speeds.
The invention relates to switches whose function is to route calls or messages individually. Also, if the signals are transmitted in packet mode, the switch must route all the packets present at the respective inputs to designated outputs and then change configuration to route subsequent packets.
FIG. 1
is a block diagram of a prior art switch
10
that implements the above function. It has N inputs
10
1
,
10
2
, . . .
10
N
each of which is adapted to be connected to a respective optical fiber
12
1
12
2
, . . . ,
12
N
. Each fiber transmits m channels consisting of m respective carriers at different wavelengths &lgr;
1
, &lgr;
2
, . . . , &lgr;
m
modulated by pulses and by packets.
Each input
10
1
,
10
2
, . . .
10
N
is connected to a respective corresponding optical demultiplexer
13
1
, . . . ,
13
N
which separates the m carriers received at that input. Each carrier is then transmitted to a wavelength converter and regenerator device
18
1
, . . . ,
18
N
. The converted signals are recombined by an optical multiplexer
14
1
, . . . ,
14
N
. N signals G
1
, G
2
, . . . , G
N
are obtained at the output of these multiplexers. The N signals are then broadcast in m.N directions by respective couplers
15
1
, . . . ,
15
N
. They are then routed to m×N respective outputs
20
1
,
20
2
, . . . ,
20
mN
of the switch
10
by m×N respective selector units
22
1
,
22
2
, . . . ,
22
mN
. Each selector unit is in two parts, namely, for the unit
22
1
, for example, an input selector first device
24
1
and a wavelength selector second device
24
2
.
For example, the input selector device
24
1
has N inputs each of which is connected to respective outputs
16
1
to
16
N
of the converter and regenerator devices
14
1
,
14
2
, . . .
14
N
. The input selector device
24
1
selects at most one of the N received signals G
1
, G
2
, . . . , G
N
. The selected signal is then routed to the wavelength selector device
24
2
. From the m carriers of the signal selected, the latter device selects one carrier to be transmitted to an output
20
1
of the switch
10
. The signals supplied at the outputs
20
1
,
20
2
, . . . ,
20
mN
are then grouped into groups of m signals having different wavelengths &lgr;
1
, &lgr;
2
, . . . , &lgr;
m
by multiplexers
14
1
, . . . ,
14
N
so that they can be transmitted via optical fibers
13
1
, . . . ,
13
N
.
In other embodiments, the number of output fibers and the number of channels per output fiber can be different from N and m, respectively. On the other hand, the total number m.N of output channels is equal to the total number of input channels.
Each input selector device
24
1
, etc. includes at least N selector units, for example optical amplifiers used as optical gates. Each wavelength selector device
24
2
, etc. includes at least m selector units consisting of optical amplifiers used as optical gates, for example, and wavelength-selective means. The switch
10
therefore includes at least m.N.(m+N) optical amplifiers. This large number of components is not favorable to reliability, simplicity or optimum fabrication cost. Also, each signal G
1
, G
2
, . . . , G
N
is broadcast to an input of each of the m.N input selector units
22
1
,
22
2
, . . . ,
22
mN
. A consequence of this is that the power of each signal G
i
is divided by a factor m.N.
Furthermore, after the selection effected by the first device
24
1
, the selection operated by the second device
24
2
further divides the power of the signal by a factor equal at most to a value from N to m. Accordingly, in total, the power of each input signal is attenuated by at least a factor N.m.max(N,m). This reduction in the power of the signals in the selector device produces a low signal
oise ratio and therefore distortion, which becomes problematic for signals at very high bit rates, for example bit rates higher than 10 Gbit/s.
An object of the invention is to reduce significantly the number of times each signal is divided for the same total bit rate processed in this kind of switch. This increases the signal
oise ratio and higher information bit rates can therefore be achieved.
The invention provides a switch for optical signals, the switch including a number of outputs at least equal to the number N of inputs, for routing an input signal to at least one output, each input being adapted to receive signals modulating optical carriers having m different wavelengths, characterized in that it includes:
means for grouping all of the carriers received at an input of the switch into non-contiguous subsets of carriers;
selector units for routing in blocks the signals corresponding to each subset of optical carriers; and
means for dividing each subset and then transmitting all the carriers of that subset to the same output of the switch.
The above switch processes a whole subset of the set of wavelengths, i.e. a plurality of wavelengths, simultaneously, enabling the same single component to be used for each function, such as amplification and switching, instead of one component for each wavelength, and this applies up to the destination output. Accordingly, the signals are divided less than in the conventional optical switch shown in FIG.
1
.
In the prior art
Chiaroni Dominique
Jourdan Amaury
Le Sauze Nicolas
Penninckx Denis
Rofidal Olivia
Nguyen Khiem
Sughrue & Mion, PLLC
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