Patent Application
20110229149
Wavelength division multiplexed (WDM) optical communication systems are known in which multiple optical signals or channels, each having a different wavelength, are combined onto an optical fiber. Such systems typically include a laser associated with each wavelength, a modulator configured to modulate the optical signal output from the laser, and an optical combiner to combine each of the modulated optical signals.
Typically, the optical signals are modulated in accordance with a modulation format. Various modulation formats are known, such as on-off-keying (OOK), differential phase shift keying (DPSK), differential quadrature phase shift keying (DQPSK), quadrature phase shift keying (QPSK), and binary phase shift keying (BPSK). As generally understood, different modulation formats may have different optical characteristics. For example, certain modulation formats may be more sensitive to noise, and thus may be associated with a higher bit error rate if noise is present on a given optical link. In addition, some modulation formats may have a higher spectral density and thus can carry more data per unit of spectrum than others. Still, others may have a higher tolerance for chromatic dispersion (CD) and polarization mode dispersion (PMD) and may require little or no CD or PMD compensation for a given amount of CD or PMD.
In general, those modulation formats that have a higher spectral density, such that more information or bits are carried per unit of spectrum, will typically have less energy per bit. As a result, high spectral density modulation formats are more susceptible to transmission non-idealities, and thus will have higher bit error rates for a given amount of PMD or optical signal noise, for example. Accordingly, such modulation formats may be used to carry data at relatively higher rates over shorter distances. On the other hand, those modulation formats that require more energy per bit have will have lower bit error rates, but are spectrally less efficient. Such lower spectral density modulation formats, therefore, may be used to carry data over longer distances.
Conventional WDM systems typically include a series of printed circuit boards or cards, such that each one supplies or outputs a corresponding optical channel. Such cards typically include discrete components, such as a laser, modulator, and modulator driver circuit, which are associated with each channel. Typically, different cards are provided for different optical links, such that optical signals having an appropriate modulation format are supplied to a given link. For example, specific cards may be provided to supply signals that are transmitted over long distance links, such as those which may be used in undersea or submarine systems, while other cards may be provided to supply signals to shorter distance terrestrial links. Thus, cards are often tailored for different optical links. As a result, the costs for manufacturing each card may be excessive and there may be no flexibility to trade off capacity and reach when deploying in various network links
Consistent with the present disclosure, a transmitter is provided that includes a control circuit configured to selectively supply one of first control signals and one of second control signals. A driver circuit is also provided that is coupled to the control circuit and is configured to output a first plurality of drive signals in response to the first control signals and a second plurality of drive signals in response to the second control signals. In addition, a substrate is provided and a plurality of modulators is provided on the substrate. Each of the plurality of modulators is coupled to the driver circuit, and each of the plurality of modulators is configured to supply a corresponding one of a plurality of modulated optical signals, such that, in response to the first plurality of drive signals, the modulated optical signals have a first modulation format, and, in response to the second plurality of drive signals, the modulated optical signals have a second modulation format different than the first modulation format.
Consistent with an additional aspect of the present disclosure, a transmitter is provided that includes a control circuit coupled to the driver circuit. The control circuit is configured to selectively supply first, second, third, and fourth control signals. In addition, a driver circuit is provided that is configured to output first, second, third, and fourth pluralities of drive signals in response to the first, second, third, and fourth control signals, respectively. Moreover a substrate is provided and a plurality of optical outputs is provided on the substrate. Wherein, first ones of the plurality of optical outputs supply first light having a first polarization in response to the first plurality of drive signals, and second ones of the plurality of optical outputs are deactivated in response to the second plurality of drive signals. In addition, the first ones of the plurality of optical outputs are deactivated in response to the third plurality of drive signals, and the second ones of the plurality of optical outputs supply second light having a second polarization in response to the fourth plurality of drive signals.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments and together with the description, serve to explain the principles of the disclosure.
a-3c shows a portion of the transmitter photonic integrated circuit shown in
a-4c illustrates examples of constellations of modulated optical signals generated in accordance with an additional aspect of the present disclosure; and
Consistent with the present disclosure, a compact multichannel transmitter is provided that can generate optical signals having different modulation formats depending on optical link requirements. Preferably, the transmitter includes a photonic integrated circuit having multiple lasers and modulators. A control circuit adjusts the drive signals supplied to the modulators such that optical signals having a desired modulation format may be output from the modulators. Thus, for example, the transmitter may be used to output optical signals having a modulation format suitable for long haul or submarine links, as well as for links having a shorter distance. Moreover, the same photonic integrated circuit may supply optical signals with different modulation formats, such that, for example, those optical signals that are dropped along a link, and thus travel a shorter distance, may have a first modulation format, while other optical signals that travel the entire length of the link may have a second modulation format that is more suited for longer distances. Accordingly, instead of designing and manufacturing different transmitters, the same transmitter, for example, may be used to output optical signals for transmission on a variety of different links.
Reference will now be made in detail to the present exemplary embodiments, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
As further shown in
a shows optical source OS-1 in greater detail. It is understood that remaining optical sources OS-1 to OS-m have the same or similar structure as optical source OS-1. As discussed in greater detail below,
Optical source OS-1 includes a laser 108, for example, a distributed feedback laser (DFB) to supply light to at least four (4) modulators 106, 112, 126 and 130. In particular, DFB 108 outputs continuous wave (CW) light to a dual output splitter or coupler 110 (e.g. a 3 db coupler) having an input port and first and second output ports. Typically, the waveguides used to connect the various components of optical source OS-1 may be polarization dependent. A first output 110a of coupler 110 supplies the CW light to first branching unit 111 and the second output 110b supplies the CW light to second branching unit 113. A first output 111a of branching unit 111 is coupled to modulator 106 and a second output 111b is coupled to modulator 112. Similarly, first output 113a is coupled to modulator 126 and second output 113b is coupled to modulator 130. Modulators 106, 112, 126 and 130 may be, for example, Mach Zender (MZ) modulators. Each of the MZ modulators receives CW light from DFB 108 and splits the light between two (2) arms or paths. An applied electric field in one or both paths of a MZ modulator creates a change in the refractive index. In one example, if the relative phase between the signals traveling through each path is 180° out of phase, destructive interference results and the signal is blocked. If the signals traveling through each path are in phase, the light may pass through the device and modulated with an associated data stream. The applied electric field may also cause changes in the refractive index such that a phase of light output from the MZ modulator is shifted or changed relative to light input to the MZ modulator. Thus, appropriate changes in the electric field can cause changes in phase of the light output from the MZ modulator.
Each of the MZ modulators 106, 112, 126 and 130 are driven with data signals or drive signals supplied via driver circuits 104, 116, 122 and 132 respectively. In particular, a first processed data stream D1 at a data rate of, for example, 10 Gbit/second, is supplied on line 140 to pre-coder circuit 102. Pre-coder circuit 102 may perform differential encoding on processed data stream D1. The encoded data is supplied to driver circuit 104 which supplies drive signals that drive MZ modulator 106. The CW light supplied to MZ modulator 106 via DFB 108 and branching unit 111 is modulated with the encoded data from driver circuit 104. The modulated data signal from MZ modulator 106 is supplied to first input 115a of branching unit 115. Similarly, a second processed data stream D2 which may also be at a data rate of, for example, 10 Gbit/second, is supplied on line 142 to pre-coder circuit 118 which also performs differential encoding. The encoded data is then supplied to driver circuit 116 which supplies further drive signals for driving MZ modulator 112. The CW light supplied to MZ modulator 112 via DFB 108 and branching unit 111 is modulated with the encoded data carried by drive signals from driver circuit 116. The modulated data signal from MZ modulator 112 is supplied to phase shifter 114 which shifts the phase of the signal 90° (π/2) to generate one of an in-phase (I) or quadrature (Q) components, which is supplied to second input 115b of branching unit 115. The modulated data signals from MZ modulator 106, which includes the other of the I and Q components, and from MZ modulator 112 are supplied to polarization beam combiner (PBC) 138 via branching unit 115.
A third processed data stream D3 is supplied on line 144 to pre-coder circuit 120, which also differentially encodes the received data. The encoded data is supplied to driver circuit 122 which, in turn, supplies drive signals for driving MZ modulator 126. MZ modulator 126, in turn, outputs modulated optical signals as one of the I and Q components. A polarization rotator 124 may optionally be disposed between coupler 110 and branching unit 113. Polarization rotator 124 may be a two port device that rotates the polarization of light propagating through the device by a particular angle, usually an odd multiple of 90°. The CW light supplied from DFB 108 is rotated by polarization rotator 124 and is supplied to MZ modulator 126 via first output 113a of branching unit 113. MZ modulator 126 then modulates the polarization rotated CW light supplied by DFB 108, in accordance with drive signals from driver circuit 122. Such drive signals are output in response to encoded data received by driver circuit 122. The modulated data signal from MZ modulator 126 is supplied to first input 117a of branching unit 117.
A fourth processed data stream 146 which may also be at a data rate of, for example, 10 Gbit/second, is supplied to pre-coder circuit 134 which differentially encodes the received data. The encoded data is supplied to driver circuit 132 which supplies drive signals for driving MZ modulator 130. The CW light supplied from DFB 108 is also rotated by polarization rotator 124 and is supplied to MZ modulator 130 via second output 113b of branching unit 113. MZ modulator 130 then modulates the received optical signal in accordance with encoded data received from driver 132. The modulated data signal from MZ modulator 130 is supplied to phase shifter 128 which shifts the phase the incoming signal 90° (π/2) and supplies the other of the I and Q components to second input 117b of branching unit 117. Alternatively, polarization rotator 136 may be disposed between branching unit 117 and PBC 138 and replaces rotator 124. In that case, the polarization rotator 136 rotates both the modulated signals from MZ modulators 126 and 130 rather than the CW signal from DFB 108 before modulation. The modulated data signal from MZ modulator 126 is supplied to first input port 138a of polarization beam combiner (PBC) 138. The modulated data signal from MZ modulator 130 is supplied to second input port 138b of polarization beam combiner (PBC) 138. PBC 138 combines all four (4) of the modulated data signals from branching units 115 and 117 and outputs a multiplexed optical signal to output port 138c. In this manner, one DFB laser 108 provides a CW signal to four (4) separate MZ modulators 106, 112, 126 and 130 for modulating at least four (4) separate data channels by utilizing phase shifting and polarization rotation of the transmission signals. Conventionally, multiple CW light sources were used for each channel which increased device complexity, chip real estate, power requirements and associated manufacturing costs.
Alternatively, splitter or coupler 110 may be omitted and DFB 108 may be configured as a dual output laser source to provide CW light to each of the MZ modulators 106, 112, 126 and 130 via branching units 111 and 113. In particular, coupler 110 may be replaced by DFB 108 configured as a back facet output device. Both outputs of DFB laser 108, from respective sides 108-1 and 108-2 of DFB 108, are used, in this example, to realize a dual output signal source. A first output 108a of DFB 108 supplies CW light to branching unit 111 connected to MZ modulators 106 and 112. The back facet or second output 108b of DFB 108 supplies CW light branching unit nit 113 connected to MZ modulators 126 and 130 via path or waveguide 143 (represented as a dashed line in
The polarization multiplexed output from PBC 138, may be supplied to multiplexer 204 in
In the example shown in
Alternatively, consistent with a further aspect of the present disclosure and in response to additional control signals from control circuit 207, processed duplicate data streams DB may be omitted so that no modulated optical signals having the second polarization are supplied to PBC 138. In addition, modulators 126 and 130 may be deactivated, so that a DPSK modulated optical signal having one polarization may be output from PBC 138.
Consistent with a further aspect of the present disclosure, pre-coder circuits 102, 118, 120, and 134 may be configured to encode the processed data D1, D2, D3, and D4 (in
Thus, in response to control signals output from control circuit 207, data signals D1 to D4 may be supplied to precoder circuits 102, 118, 120, and 134, such that first and second QPSK modulated optical signals, having first and second polarizations, respectively, are supplied to PBC 138. Alternatively, in a manner similar to that noted above in connection with
Optionally, in response to additional control signals output from control circuit 207, the same data may be supplied on lines 140 and 142, while no data is output on lines 144 and 146. In that case, as in
BPSK signals, like the DPSK signals discussed above, have lower spectral efficiency, but a higher OSNR than QPSK modulated signals. Accordingly, BPSK signals are better suited for longer distance links, and QPSK signals may be transmitted over shorter ones. In the examples discussed above, by appropriate application of the control signals output from control circuit 207, the same PICs and input circuits may be used to supply optical signals having different modulation formats. Thus, consistent with the present disclosure, instead of manufacturing different transmitters for different optical fiber links, such that each transmitter is tailored for a particular optical fiber link, for example, the same transmitter may be controlled to output optical signals having different modulation formats, and, therefore, may be used for a variety of optical fiber links.
In the example shown in
Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.
