INFINERA CORPORATION Patent applications |
Patent application number | Title | Published |
20160118361 | INTEGRATED CIRCUIT PACKAGE STRUCTURE AND INTERFACE AND CONDUCTIVE CONNECTOR ELEMENT FOR USE WITH SAME - Consistent with the present disclosure, a conductive connector element for use with a rigid or flexible insulating substrate to electrically couple first and second electrically conductive contact surfaces is provided. The conductive connector element comprises an electrically conductive deformable material and a shape-memory alloy. The conductive connector element is sized and shaped to fit in an opening provided through the insulating substrate and the shape-memory alloy and the electrically conductive deformable material are mechanically coupled such that a thermally induced deformation of the shape-memory alloy causes a mechanical deformation of the electrically conductive deformable material and thereby aids in the electrical coupling of the first and second electrically conductive contact surfaces through the connector element when the connector element is disposed in the opening provided through the insulating substrate. IC package structures and interfaces incorporating such conductive connector elements are also provided. | 04-28-2016 |
20160033728 | HYBRID POLARIZATION-MULTIPLEXED COHERENT PIC TRANSMITTERS AND RECEIVERS - Consistent with the present disclosure, active devices, such as lasers, optical amplifiers, and photodiodes, are integrated on a first substrate, and other optical devices, such as passive devices including polarization rotators and polarization beam combiners, are provided on a second substrate. An array of lenses is provided between the two substrates to provide a low loss optical connection from the first substrate to the second substrate. In addition, the orientation or position of the lenses can be readily controlled with Microelectromechnical System (MEMS) actuators so that the light can be directed precisely to a desired optical element, such as a waveguide. Consistent with a further aspect of the present disclosure, the lenses may be controlled to be misaligned by varying degrees in order to control the amount of light that is supplied from one substrate to another. Accordingly, the lenses may act as variable optical attenuators to provide uniform optical power levels, for example, or any desired power distribution. | 02-04-2016 |
20150280853 | CONFIGURABLE FREQUENCY DOMAIN EQUALIZER FOR DISPERSION COMPENSATION OF MULTIPLE SUB-CARRIERS - A system may include an optical transmitter and an optical receiver. The optical transmitter may generate optical signals associated with sub-carriers, and may provide the optical signals via an optical link. The optical receiver may receive the optical signals via the optical link, and may generate samples based on the optical signals. The samples may be associated with the sub-carriers. The optical receiver may combine the samples to form a time domain sample vector having a particular size, and may generate a frequency domain sample vector, having the particular size, based on the time domain sample vector. The optical receiver may demultiplex the frequency domain sample vector to generate domain sample vectors corresponding to the sub-carriers. The optical receiver may process the frequency domain sample vectors to generate equalized frequency domain sample vectors, and may output the equalized frequency domain sample vectors. | 10-01-2015 |
20150280834 | FREQUENCY AND PHASE COMPENSATION FOR MODULATION FORMATS USING MULTIPLE SUB-CARRIERS - An optical receiver may receive input signals carried by respective sub-carriers. The optical receiver may determine, based on the input signals, a compensation value to be used to modify an input signal. The optical receiver may use the compensation value to adjust the input signal to form a modified input signal. The compensation value may be used to modify a frequency or a phase of the input signal. The optical receiver may determine, based on the modified input signal, a phase estimate value that represents an estimated phase associated with the input signal. The optical receiver may combine the compensation value and the phase estimate value to form a phase adjustment signal, may combine the input signal and the phase adjustment signal to form an output signal, and may output the output signal. | 10-01-2015 |
20150280833 | ACCURATE CALCULATION OF POLARIZATION MODE DISPERSION USING BLIND EQUALIZATION - A digital signal processor (DSP) may receive a signal that has an x-polarization (x-pol) and a y-polarization (y-pol). The DSP may equalize the x-pol of the signal and the y-pol of the signal based on filter coefficients determined using a constant modulus algorithm (CMA). The DSP may perform phase correction on the equalized x-pol signal and the equalized y-pol signal. The DSP may identify a first frame header pattern within the phase-corrected x-pol signal, and may identify a second frame header pattern within the phase-corrected y-pol signal. The DSP may determine, based on the first frame header pattern and the second frame header pattern, a quantity of lock-in differential group delay (DGD). The device may adjust one or more of the filter coefficients to remove the quantity of lock-in DGD and to permit an amount of polarization mode dispersion to be determined based on the filter coefficients. | 10-01-2015 |
20150280814 | ESTIMATING PHASE USING TEST PHASES AND INTERPOLATION FOR MODULATION FORMATS USING MULTIPLE SUB-CARRIERS - An optical receiver may receive input signals carried by sub-carriers, and may apply test phases to each input signal. The optical receiver may determine error values, associated with test phases, for each input signal. The optical receiver may calculate updated metric values, associated with the test phases, for a particular input signal, based on a first error value and a second error value. The first error value may be associated with a first sub-carrier, and the second error value may be associated with a second sub-carrier. The optical receiver may compare the updated metric values associated with the particular input signal, and may determine a test phase that represents an estimated phase, associated with the particular input signal, based on the comparison. The optical receiver may determine a phase estimate value based on the test phase, and may provide the phase estimate value to modify the particular input signal. | 10-01-2015 |
20150188276 | MULTIPLEXER HAVING ASE SUPPRESSION - Consistent with the present disclosure, optical filters are provided in a reconfigurable optical add-drop multiplexer (ROADM). In one example, groups of optical signals are amplified by corresponding erbium-doped fiber amplifiers (EDFAs) and supplied to each optical filter, which has a passband that includes the wavelengths associated with the received optical signal group. Light at wavelengths outside the passband of each optical filter, such as amplified stimulated emission (ASE) light generated by a respective EDFA, is significantly attenuated. Each optical signal group, after such amplification and filtering may then be switched and combined in a multicast switch before being directed toward a desired optical communication path. When, for example, first and second optical signal groups are combined, however, the first optical signal group is accompanied by little or no ASE light at the second optical signal group wavelengths. In addition, the second optical signal group is not accompanied by significant ASE light at the first optical signal group wavelengths. Accordingly, the first and second optical signal groups have less noise than would otherwise be present in the absence of the optical filters, and bit error rates associated with the optical signal groups are reduced. | 07-02-2015 |
20150093117 | OPTICAL TRANSFER LINEARITY USING TEST TONES - An optical system may have an optical transmitter including a digital signal processor to receive a signal channel, determine a digital signal associated with the signal channel based on information in a look-up table and based on a test tone, and output the digital signal. The optical system may further have a digital-to-analog converter to convert the digital signal to an analog signal, a laser to provide an optical signal, and a modulator to receive the optical signal and the analog signal, and modulate the optical signal based on the analog signal to form a modulated optical signal. The optical system may also have a photodiode to convert the modulated optical signal to a digital signal, a tone detector to detect the test tone based on the digital signal, and a controller to modify the information in the look-up table based on the test tone. | 04-02-2015 |
20150049984 | OPTICAL HYBRID MIXER WITHOUT WAVEGUIDE CROSSINGS - A multimoded interference coupler may include: first and second inputs to receive first and second optical signals such that light is not supplied through any portion of a first gap extending between the first and second inputs; first and second outputs to provide first and second components associated with the first and second optical signals, such that light is not output through any portion of a second gap extending between the first and second outputs. The first and second inputs may be separated by a first distance. The first and second outputs may be separated by the first distance. The first input and the second output may be separated by a second distance being different than a third distance separating the second input and the first output. The first and second components may have a phase difference based on a difference between the second and third distances. | 02-19-2015 |
20150030333 | HAMMING CODED MODULATION - An optical system may include a digital signal processor (DSP) to receive first samples of a digital signal. The first samples may be Hamming encoded. The DSP may correlate the first samples to multiple groups of second samples to determine multiple correlation values. Each of the multiple groups of second samples may correspond to respective code words. Each of the multiple correlation values may correspond to a correlation measurement between the first samples and each of the multiple groups of second samples. The DSP may determine a particular code word, of the multiple code words, corresponding to one of the correlation values of the multiple correlation values; determine output bits based on bits of the particular code word and the one of the correlation values; and provide the output bits. The output bits may include data associated with the digital signal. | 01-29-2015 |
20150023659 | CLOCK PHASE DETECTION IN THE FREQUENCY DOMAIN - A digital signal processor (DSP) may receive samples of a signal from an analog-to-digital converter (ADC); convert the samples from a time domain to a frequency domain; determine a clock phase error of the samples while in the frequency domain; and provide a voltage corresponding to the clock phase error. The voltage may be provided to reduce timing errors associated with the samples. | 01-22-2015 |
20140328584 | REDUCING PHASE NOISE ASSOCIATED WITH OPTICAL SOURCES - An optical transmitter may include an optical source to provide a first optical signal having a varying frequency; an optical circuit to receive a portion of the first optical signal and provide a second optical signal corresponding to a change in frequency of the first optical signal; a photodetector to receive the first optical signal and provide an electrical signal that is indicative of the change in frequency of the first optical signal; an integrator to receive the electrical signal and provide an inverted electrical signal; and a controller to process the inverted electrical signal and provide a current, associated with the inverted electrical signal, to the optical source. The optical source may reduce the phase noise associated with the first optical signal based on the current. | 11-06-2014 |
20140297865 | DYNAMIC ACTIVATION OF PRE-DEPLOYED NETWORK RESOURCES - A network device may receive an activation instruction. The network device may provide network resources. The activation instruction may request the network device to activate a particular network resource that is deactivated. The activation instruction may be associated with a license that identifies the particular network resource and identifies a resource request of a user. The network device may configure, based on the activation instruction, a component of the network device to activate the particular network resource. The component, after being configured to activate the particular network resource, may allow data flows, received by the network device, to be provided towards a destination device using the particular network resource. The network device may receive a data flow and provide, by the component of the network device, the data flow towards the destination device using the particular network resource. | 10-02-2014 |
20140294381 | ADJUSTING CARRIER SPACING IN A CHANNEL - An optical system may include optical transmitters to provide respective optical signals. Each of the respective optical signals may provide one or more carriers in an optical channel. The optical channel may include multiple carriers associated with the respective optical signals. First and second carriers, of the multiple carriers, may have a particular carrier space width. The particular carrier space width may include a frequency error associated with one or more optical signals of the respective optical signals. The optical system may include a control system to determine the frequency error and cause one or more of the optical transmitters to adjust the particular carrier space width based on the adjusted frequency error. | 10-02-2014 |
20140185979 | LIGHT ABSORPTION AND SCATTERING DEVICES IN A PHOTONIC INTEGRATED CIRCUIT - A photonic integrated circuit is provided that may include a substrate; one or more optical sources, on the substrate, to output light associated with a corresponding one or more optical signals; one or more waveguides connected to the one or more optical sources; a multiplexer connected to the one or more waveguides; and one or more light absorptive structures, located on the substrate adjacent to one of the one or more optical sources, one of the one or more waveguides, and/or the multiplexer, to absorb a portion of the light associated with at least one of the corresponding one or more optical signals. | 07-03-2014 |
20140178065 | NONLINEARITY COMPENSATION USING PILOT TONES - An optical system may have an optical transmitter including a digital signal processor to receive a signal channel, add data corresponding to a pilot tone, generate a digital signal associated with the signal channel and including the pilot tone, and output the digital signal. The optical system may further have a digital-to-analog converter to convert the digital signal to an analog signal, a laser to provide an optical signal, and a modulator to receive the optical signal and the analog signal, and modulate the optical signal based on the analog signal to form a modulated optical signal. The modulated optical signal may include the pilot tone. The optical system may also have an optical receiver to receive the modulated optical signal, process the modulated optical signal to determine a phase associated with the pilot tone, and apply the phase to the modulated optical signal to recover the signal channel. | 06-26-2014 |
20140173538 | FEC DECODER DYNAMIC POWER OPTIMIZATION - A computing device is configured to analyze a logic gate design having logic gates. The computing device is configured further to identify logic gates that are affected by toggling activity associated with an input of one or more of the logic gates. The computing device is configured further to replace, within the logic gate design, the identified logic gates with different logic gates that are not affected by the toggling activity; and output a new logic gate design based on replacing the identified logic gates with the different logic gates, the application specific integrated circuit, with the new logic gate design, producing a same output as the application specific integrated circuit with the logic gate design, based on same inputs. | 06-19-2014 |
20140169788 | QUALITY OF SERVICE APPLICATION FOR DIFFERENT DATA FLOW TYPES - A network device is configured to store parameters identifying a respective quality of service (QoS) to apply to corresponding different types of data flows; initiate establishment of a network channel between a source device and a destination device through an optical network; receive first and second data flows destined for the destination device, where the first data flow and the second data flow may have first and second data flow types; identify a first QoS and a different second QoS to apply to the first and second data flows based on the first and second data flow types and based on the parameters; apply the first QoS to the first data flow and the second QoS to the second data flow to form processed first and second data flows; and transmit, via the network channel, the processed first and second data flows towards the destination device. | 06-19-2014 |
20140169787 | OPTICAL AMPLIFIER CONTROLLER - A controller is configured to determine a first amount of current associated with a first power level. The controller is configured further to generate a digital pulse signal based on the first amount of current, where the digital pulse signal may have a second power level and an associated duty cycle. The controller is configured further to convert the digital pulse signal into a second amount of current and output the second amount of current as a pulse signal based on the duty cycle. | 06-19-2014 |
20140160679 | INTERFACE CARD COOLING UISNG HEAT PIPES - A device may have: a frame section having a cage with a first receiving portion and a second receiving portion, the second receiving portion receiving a module; a first plate having an end, the first plate being received by the first receiving portion; a heat pipe having a first end attached to the end of the first plate and having a second end; a second plate attached to the second end of the heat pipe; and a spring attached to the first plate to bias the first plate against the module, the first plate being capable of receiving heat dissipated by the module, the heat pipe being capable of receiving the heat received by the first plate and transferring the heat to the second plate, the second plate receiving the heat transferred by the heat pipe and dissipating the received heat. | 06-12-2014 |
20140156751 | BACKWARD-RECURSIVE PATH COMPUTATION USING RSVP-TE - One or more nodes, in a network, are configured to transmit a message, for computing diverse paths through the network from a first domain to a second domain using a Resource Reservation Protocol—Traffic Engineering (RSVP-TE) signaling protocol; generate at least one data structure that identifies multiple diverse entry points to the second domain; transmit the at least one data structure toward the first domain; complete the at least one data structure to form at least one completed data structure; use a first data structure, of the at least one completed data structure, to compute a primary path from the first domain to the second domain; and use a second data structure, of the at least one completed data structure, to compute a secondary path from the first domain to the second domain. | 06-05-2014 |
20140147106 | RAPID RECOVERY IN PACKET AND OPTICAL NETWORKS - A node may determine a failure in a first path for routing first optical network traffic between a first set of networking devices, where the first path includes a first set of optical transport nodes. The node may determine a second path for routing the first optical network traffic between the first set of networking devices, where the second path includes a second set of optical transport nodes that route second optical network traffic between a second set of networking devices. The second set of optical transport nodes may include at least one node that is not included in the first set of optical transport nodes. The node may pre-empt routing of the second optical network traffic via the second path, and may route the first optical network traffic via the second path after pre-empting routing of the second optical network traffic via the second path. | 05-29-2014 |
20140133868 | INTENSITY-BASED MODULATOR - An optical modulator includes a splitter, phase modulators, amplitude modulators, intensity modulators, and a combiner. The splitter is configured to receive light, and split the light into portions of the light. Each of the phase modulators is configured to receive a corresponding one of the portions of the light, and modulate a phase of the portion of the light to provide a phase-modulated signal. Each of the amplitude modulators is configured to receive a corresponding one of the phase-modulated signals, and modulate an amplitude of the phase-modulated signal to provide an amplitude-modulated signal. Each of the intensity modulators is configured to receive a corresponding one of the amplitude-modulated signals, and modulate an intensity of the amplitude-modulated signals to provide an intensity-modulated signal. The combiner is configured to receive the intensity-modulated signals, combine the intensity-modulated signals into a combined signal, and output the combined signal. | 05-15-2014 |
20140133795 | SCATTERING DEVICE ON AN ARRAYED WAVEGUIDE GRATING - An optical device may include a substrate; an arrayed waveguide grating provided on the substrate and having first and second slabs; multiple first waveguides extending from the first slab, the multiple first waveguides may supply respective first optical signals to the first slab; multiple second waveguides extending from the second slab, the multiple second waveguides may supply respective second optical signals to the second slab; a third waveguide extending from the second slab, the third waveguide outputting a third optical signal from the second slab, the third optical signal including the first optical signals; a fourth waveguide extending from the first slab, the fourth waveguide may output a fourth optical signal from the first slab, the fourth optical signal including the second optical signals; and a first scattering device optically coupled to a portion of an edge of the first slab between the multiple first waveguides and the fourth waveguide. | 05-15-2014 |
20140133793 | POLARIZATION BEAM SPLITTER - An optical system may include: a polarization beam splitter having: a first end having an input configured to receive multiple optical signals; a second end having a first output and a second output, where the first output may provide first components, having a first polarization of the multiple optical signals, and the second output may provide second components, having a second polarization, of the multiple optical signals; and a first waveguide having a first width and a second waveguide having a second width, where the first waveguide and the second waveguide may each have a length corresponding to a difference between the first width and the second width, where the first waveguide and the second waveguide may be configured to induce a phase shift of the plurality of optical signals based on the first width, the second width, and the length of the first waveguide and the second waveguide. | 05-15-2014 |
20140093253 | DUAL-DRIVE MODULATOR - A transmitter module includes a processor configured to receive input data, and determine input values corresponding to the input data; a digital-to-analog converter configured to receive the input values from the processor, and generate first and second voltage signals based on the input values; a laser configured to output light; a Mach-Zehnder modulator configured to receive the light from the laser and the first and second voltage signals from the digital-to-analog converter, and modulate the light based on the first and second voltage signals to generate a modulated optical signal that includes distortion; and a filter configured to receive the modulated optical signal from the modulator, process the modulated optical signal to reduce or eliminate the distortion and produce an output optical signal, and output the output optical signal. | 04-03-2014 |
20140093240 | NONLINEAR COMPENSATION IN WDM SYSTEMS - A compensator device may include a selection switch to receive a first optical signal and provide first and second groups of channels associated with the first optical signal; a polarization beam splitter to receive the first channels, and provide first and second components; a photodiode that provides an electrical signal indicative of an intensity of the first group of channels; a first modulator to receive the electrical signal and the first components and to modulate the first components to form first modulated channels; a second modulator to receive the electrical signal and the second components to modulate the second components to form second modulated channels; a polarization beam combiner to receive the first and second modulated channels to form combined modulated channels; and a coupler to receive the combined modulated channels and the second group of channels to form a second optical signal. | 04-03-2014 |
20140092924 | CHANNEL CARRYING MULTIPLE DIGITAL SUBCARRIERS - An optical system includes a transmitter module and/or a receiver module. The transmitter module is configured to receive input data, map the input data to a set of subcarriers associated with an optical communication channel, independently apply spectral shaping to each of the subcarriers, generate input values based on the spectral shaping of each of the subcarriers, generate voltage signals based on the input values, modulate light based on the voltage signals to generate an output optical signal that includes the subcarriers, and output the output optical signal. The receiver module is configured to receive the output optical signal, convert the output optical signal to a set of voltage signals, generate digital samples based on the set of voltage signals, independently process the digital samples for each of the subcarriers, map the processed digital samples to produce output data, and output the output data. | 04-03-2014 |
20140089619 | OBJECT REPLICATION FRAMEWORK FOR A DISTRIBUTED COMPUTING ENVIRONMENT - A device may receive information that identifies a data item and a data item operation. The device may store a first sequence identifier, a data item reference that references the data item, and an operation reference that references the operation. The first sequence identifier may reference the data item and operation references, and may indicate an order in which the first sequence identifier is stored. The device may store the data item in a memory location, may store an identification of the memory location, may remove a reference to the data item by a previous sequence identifier, and/or may add the data item, may modify the data item, or may delete the data item depending on whether the operation is an add operation, a modify operation, or a delete operation. The device may transmit, to a slave device, the first sequence identifier, the data item reference, and the operation reference. | 03-27-2014 |
20140016894 | SUPPRESSION OF RESONANT POLARIZATION CONVERSION IN PHOTONIC INTEGRATED CIRCUITS - A device may include a number of optical waveguides, each of which being spaced from one another. The optical waveguides may each include at least one curved section and widths of the curved sections of the optical waveguides may be selected to reduce polarization conversion of light traversing the birefringent optical waveguides. | 01-16-2014 |
20140006961 | DIGITAL LINK VIEWER | 01-02-2014 |
20140006959 | DIGITAL LINK VIEWER | 01-02-2014 |
20140006958 | DIGITAL LINK VIEWER | 01-02-2014 |
20140006957 | DIGITAL LINK VIEWER | 01-02-2014 |
20140006956 | DIGITAL LINK VIEWER | 01-02-2014 |
20140003824 | EQUALIZATION MECHANISM FOR PROCESSING TRAFFIC BASED ON THREE-QUADRATURE AMPLITUDE MODULATION (3QAM) | 01-02-2014 |
20140003814 | PROCESSING THREE-QUADRATURE AMPLITUDE MODULATION (3QAM) TRAFFIC USING A FOUR-BIT PHASE MODULATION SCHEME | 01-02-2014 |
20140003812 | OPTICAL BANDWIDTH MANAGER | 01-02-2014 |
20140003764 | POLARIZATION MATERIAL ON AN OPTICAL MULTIPLEXER OR AN OPTICAL DEMULTIPLEXER | 01-02-2014 |
20140003763 | COHERENT DETECTION FOR AN INTEGRATED CIRCUIT HAVING A MULTIPLEXER OR A DEMULTIPLEXER WITH A SHARED PROPAGATION REGION | 01-02-2014 |
20140003759 | SHARED PROPAGATION REGION FOR AN OPTICAL MULTIPLEXER OR AN OPTICAL DEMULTIPLEXER | 01-02-2014 |
20140001347 | ROTATOR EXTERNAL TO PHOTONIC INTEGRATED CIRCUIT | 01-02-2014 |
20130279911 | RAMAN PUMP CIRCUIT - A Raman pump may include a dual output laser configured to output two optical signals; a delay interferometer configured to delay a first of the two optical signals to decorrelate the two optical signals from each other; and a combiner configured to combine the delayed first of the two optical signals and a second of the two optical signals to provide a Raman amplification signal. | 10-24-2013 |
20130279910 | Banded Semiconductor Optical Amplifier - A semiconductor optical amplifier module may include a beam splitter to split an optical signal into two polarization optical signals including a first polarization optical signal with a Transverse Magnetic (TM) polarization provided along a first path of two paths, and a second polarization optical signal with a Transverse Electric (TE) polarization provided along a second path of the two paths; a first rotator to rotate the TM polarization of the first polarization optical signal to TE polarization; a first semiconductor optical amplifier to amplify the rotated first polarization optical signal to output a first resultant optical signal; a second semiconductor optical amplifier to amplify the second polarization optical signal; and a second rotator to rotate the polarization of the amplified second polarization optical signal to output a second resultant optical signal; and a beam combiner to combine the first resultant optical signal and the second resultant optical signal. | 10-24-2013 |
20130262954 | REDUCING PROCESSING COMPLEXITY AND COST ASSOCIATED WITH A SOFT FORWARD ERROR CORRECTION (FEC) OPERATION - A system is configured to receive a word on which to perform forward error correction; identify least reliable positions that correspond to encoded bits, within the word, associated with a lowest level of reliability; generate candidate words based on different combinations of inverted encoded bits; identify a pair of candidate words that includes a candidate word and another candidate word, the candidate word includes an inverted most reliable bit of the encoded bits within the candidate word; identify a quantity of errors within the candidate word; determine whether the quantity of errors corresponds to an odd value; invert a parity bit associated with the candidate word when the quantity of errors corresponds to the odd value; select the other candidate word when the parity bit is inverted; and perform forward error correction, on the word, using the other candidate word based on selection of the other candidate word. | 10-03-2013 |
20130262084 | ITERATIVE FORWARD ERROR CORRECTION (FEC) ON SEGMENTED WORDS USING A SOFT-METRIC ARITHMETIC SCHEME - A system is to receive a word on which to perform error correction; obtain segments, from the word, each segment including a respective subset of samples; update, on a per segment basis, the word based on extrinsic information associated with a previous word; identify sets of least reliable positions (LRPs) associated with the segments; create a subset of LRPs based on a subset of samples within the sets of LRPs; generate candidate words based on the subset of LRPs; identify errors within the word or the candidate words; update, using the extrinsic information, a segment of the word that includes an error; determine distances between the candidate words and the updated word that includes the updated segment; identify best words associated with shortest distances; and perform error correction, on a next word, using other extrinsic information that is based on the best words. | 10-03-2013 |
20130259492 | REDUCING PROCESSING BIAS IN A SOFT FORWARD ERROR CORRECTION (FEC) DECODER - A system is configured to receive a word that includes a group of samples; randomly select a subset of the samples; identify first samples, from the subset, with a lowest level of reliability; select another subset of the samples; identify second samples, from the other subset, with a lowest level of reliability; and create a merged subset based on selected first samples and selected second samples. The system is also configured to select a further subset of the samples; identify third samples, from the further subset, with a lowest level of reliability; identify fourth samples, from the merged subset, associated with a lowest level of reliability; create another merged subset based on a greater probability that fourth samples than third samples are included in the other merged subset; and generate another word based a sample from the other merged subset; and process the word using the other word. | 10-03-2013 |
20130173984 | FORWARD ERROR CORRECTION (FEC) CONVERGENCE BY CONTROLLING RELIABILITY LEVELS OF DECODED WORDS IN A SOFT FEC DECODER - A system receives a first word on which to perform error correction; identifies combinations in which encoded bits, within the first word, can be inverted; generates candidate words based on the first word and the combinations; decodes the candidate words; determines distances between the decoded words and the first word; selects, as a second word, one of the decoded words associated with a shortest distance; compares the second word to the first word to identify errors within the first word; generates a value to cause a reliability level of the first word to increase when a quantity of the errors is less than a threshold; generates another value to cause a reliability level of the first word to decrease when the quantity of the errors is not less than the threshold; and outputs a third word based on the first word, and the value or the other value. | 07-04-2013 |
20130170833 | OPTICAL COMMUNICATION SYSTEM HAVING TUNABLE SOURCES - Pairs of distributed feedback (DFB) lasers are provided on a substrate. An arrayed waveguide grating (AWG) is also provided on the substrate having input waveguides, each of which being connected to a corresponding pair of DFB lasers. The wavelengths of optical signals supplied from each pair of DFB lasers may be spectrally spaced from one another by a free spectral range (FSR) of the AWG. By selecting either a first or second DFB laser in a pair and temperature tuning to adjust the wavelength, each pair of DFB lasers can supply optical signals at one of four wavelengths, pairs of which are spectrally spaced from one another by the FSR of the AWG. A widely tunable transmitter may thus be obtained. | 07-04-2013 |
20130170831 | PHASE-MODULATED TRANSMISSION CONTROL USING EMBEDDED CONTROL SYMBOLS - A system receives a phase-modulated signal that carries client symbols and a sequence that includes first symbols on which a first tone is to be based and having a first power level, and second symbols on which a second tone is to be based and having a second power level; processes the sequence to generate the first tone and the second tone; determines a power difference based on the first power level and the second power level; retrieves condition information that identifies a threshold for determining whether a condition is associated with the signal; determines whether the power difference is greater than the threshold; and outputs an instruction, to adjust a parameter, used to transmit the signal, based on the determination that the condition is associated with the signal, where adjusting the parameter causes the power difference to decrease to a level that is less than the threshold. | 07-04-2013 |
20130170787 | OPTICAL COMMUNICATION SYSTEM HAVING TUNABLE SOURCES - Consistent with one example of the disclosed implementations, a photonic integrated circuit (PIC) may be provided that includes s group of lasers and an arrayed waveguide grating (AWG) disposed on a substrate. Each laser in the group may supply an optical signal, such that each optical signal has a different wavelength. Each laser may be tunable to at least two designated wavelengths, which are separated from one another by a free spectral range (FSR) of the AWG. As a result, the optical signals provided from each laser may be combined by the AWG, regardless of which designated wavelength the optical signals have. Accordingly, a PIC may be provided that has a relatively simple construction but can supply optical signals having tunable wavelengths. | 07-04-2013 |
20130170783 | MACH-ZEHNDER HAVING SEGMENTED DRIVE SIGNAL ELECTRODES - Consistent with the present disclosure, MZ drive signal electrodes may be provided relatively close to and parallel to one another, such that the underlying waveguide arms may also be provided close to and parallel to one another. As a result, common mode performance of an MZ modulator may be obtained. In one example, an electrode wiring configuration consistent with the present disclosure may permit a waveguide arm separation of 40 microns or less. | 07-04-2013 |
20130170782 | MACH-ZEHNDER INTERFEROMETER HAVING BENDED WAVEGUIDES - Consistent with the present disclosure, both arms of an MZ interferometer are “double-folded” and are bent in at least two locations to define first and second acute inner angles. Accordingly, the arms of the MZ interferometer may have substantially the same length, and, further, the MZ interferometer has a more compact geometry. In one example, the arms parallel each other and have a serpentine shape, and, in a further embodiment, the arms parallel one another and have a Z-shape. Accordingly, since the temperature of a PIC upon which the MZ interferometer is provided does not vary significantly over such short distances, the temperatures of both arms is substantially the same. | 07-04-2013 |
20130108273 | SUPER OPTICAL CHANNEL DATA UNIT SIGNAL SUPPORTED BY MULTIPLE WAVELENGTHS | 05-02-2013 |
20130108268 | SUPER OPTICAL CHANNEL TRANSPORT UNIT SIGNAL SUPPORTED BY MULTIPLE WAVELENGTHS | 05-02-2013 |
20130084075 | SUPER-CHANNEL ASSIGNMENT USING A FLEXIBLE GRID - A node is configured to receive an instruction to establish a channel having a bandwidth that corresponds to an operating spectrum an optical fiber; obtain information that identifies a channel spacing and a pointer that identifies where, within the spectrum, to establish bandwidth allocations; identify a group of bandwidth segments based on the spectrum and the channel spacing; and generate bit words that correspond to the bandwidth allocations, where the bit words includes bits that, when set to a value, cause sets of segments to be reserved within the spectrum, and where the sets of segments identify where the bandwidth allocations begin and end, within the spectrum, relative to the pointer. | 04-04-2013 |
20130077253 | HEAT TRANSFER USING A DURABLE LOW-FRICTION INTERFACE - A system includes a removable module to process data when installed in the system, where the module includes a first surface via which heat, that is generated by the module, is transferred. The system also includes a port into which the module is installed; and a heat sink, associated with the port, to dissipate the heat received from the first surface, where the heat sink includes a second surface on which a material is applied, and where the material makes contact with the first surface when the module is installed that allows the heat to be received from the first surface, conforms to an American Society for Testing Materials (ASTM)-B607-91 standard or a United States military specification-C-26074, and transfers the heat to the second surface that allows the module to operate at a temperature that is less than a threshold. | 03-28-2013 |
20130066679 | USING EVENTS DATA - A computer device receives a list of events, and generates possible outcomes of the events. Each one of the possible outcomes indicates which ones of the events occur and which ones of the events do not occur. The computer device receives a request for forecast information for an item associated with two or more of the events. The computer device further retrieves data, from the possible outcomes, for the item. The computer device generates the forecast, for the item, based on the data. The computer device also uses the forecast to generate a plan to provide or to provide the item or a product associated with the item. | 03-14-2013 |
20130027889 | COOLING DEVICE INSTALLATION USING A RETAINER ASSEMBLY - A system includes a retainer assembly to align each of a group of cooling devices with a corresponding electrical component of a group of electrical components that are mounted to a circuit board, where the retainer assembly includes a group of apertures, such that each of the cooling devices protrudes through a corresponding aperture when the retainer assembly is installed on the circuit board, and where the retainer assembly includes a group of retaining springs, each of which is associated with a corresponding aperture, that applies a respective force, of a group of forces, to a corresponding one of the cooling devices when the retainer assembly is installed on the circuit board. The system also includes a set of fasteners to mount the retainer assembly to the circuit board, such that the cooling devices dissipate heat that is generated by the electrical components. | 01-31-2013 |
20130022147 | COHERENT DETECTION USING COHERENT DECODING AND INTERLEAVING - A system is configured to receive a block of symbols, associated with a phase-modulated signal that includes data symbols that correspond to a payload associated with the signal, and control symbols; process the control symbols to identify an amount of phase noise associated with the control symbols; reset a phase, associated with each of the data symbols, based on the amount of phase noise and a reference phase; interleave the respective data samples, of each of the data symbols with other data samples, where the interleaved respective data samples cause errors, associated with the respective data samples, to be spread out among the other data samples and reduces an error rate relative to a prior data rate that existed before the interleaving; and perform forward error correction on the interleaved respective data samples. | 01-24-2013 |
20130011140 | SUPPRESSION OF NON-LINEAR EFFECTS IN LOW DISPERSION OPTICAL FIBERS - Consistent with the present disclosure, chromatic dispersion is introduced into an optical communication path including multiple segments or spans of dispersion shifted fiber (DSF). The chromatic dispersion generates phase mismatching between optical signals propagating along the optical communication path, i.e., the optical signals are decorrelated, such that mixing products are reduced inmagnitude, and the noise attributable to four wave mixing is correspondingly reduced. | 01-10-2013 |
20130011098 | WIDE PASSBAND AWG - Consistent with the present disclosure, an AWG is provided that has grating waveguide groupings that extend between a first free space region and a second free space region. The difference in length (ΔL) between successive grating waveguides differs for each grouping of grating waveguides, such that, for example, the ΔL associated with a given grating waveguide grouping is not an integer multiple of any of the other grating waveguide groupings. The grating waveguide groupings direct images having relatively small wavelength differences to a given output waveguide, and each grating waveguide grouping has an associated passband, which is similar to that of the conventional AWG. Unlike the conventional AWG, however, multiple grating waveguide groupings are included in the same AWG, such that the spectra associated with the grating waveguide groupings combine to provide a transmission characteristic having a passband that is greater than any individual passband. Accordingly, even if the optical signal wavelengths vary or are offset from the center wavelength of the passband, such wavelengths may still be transmitted with less loss. | 01-10-2013 |
20130007516 | ADAPTIVE VOLTAGE SCALING BASED ON THE RESULTS OF FORWARD ERROR CORRECTION PROCESSING - In one implementation, a device may include a voltage regulator circuit, a data processing circuit, and an error correction circuit, where the error correction circuit may correct errors in data processed by the data processing circuit to obtain error-corrected data and output an error-corrected version of the processed data. Additionally, an error monitor circuit may output an error signal indicative of a level of the errors in the processed data. A control circuit may receive the error signal and control the voltage regulator circuit to adjust, based on the error signal, the supply voltage to the data processing circuit. In some implementations, the control circuit may also base its decision to control the voltage regulator circuit based on available timing margins in the data processing circuit. | 01-03-2013 |
20130004158 | CHANNEL DE-SKEWING FOR A COHERENT OPTICAL RECEIVER - A system may receive a group of electrical signals from an optical receiver and via a group of channels; identify a first signal, as a reference signal, that is received via a first channel; and identify a second signal, as an orthogonal signal, that is received via a second channel, where the second signal may be orthogonal to the first signal. The system may further measure a group of skew values based on a difference in arrival times between one or more other signals, of the group of electrical signals, and the reference signal or the orthogonal signal; generate a group of de-skew values based on at least a portion of the skew values; and transmit the de-skew values, to the optical receiver, where transmitting the de-skew values allows the optical receiver to de-skew signals on the group of channels. | 01-03-2013 |
20130003753 | DISTRIBUTING CONTROL PLANE PROCESSING - A network device includes shelf controllers and interface unit controllers. An interface unit controller, of the interface unit controllers, is configured to receive a message from a different network device; determine whether a session exists for the message; identify a shelf controller, of the shelf controllers, based on the session when the session exists for the message; select the shelf controller, to receive the message, based on a load or mapping of the shelf controller when the session does not exist for the message; and transmit the message to the shelf controller. The shelf controller is configured to program a connection via a data plane of the network device. | 01-03-2013 |
20120328305 | FORWARD CARRIER RECOVERY USING FORWARD ERROR CORRECTION (FEC) FEEDBACK - A system receive, from an optical receiver, a signal derived from a first optical signal and a second optical signal generated by a local oscillator, that includes a first component that is an in-phase component and a second component that is a quadrature phase component; filter the signal, using a filter, set to one or more configurations, to obtain one or more recovered signals, where each of the recovered signals includes a respective quantity of noise; perform forward error correction, on the recovered signals, to obtain one or more quantities of bit errors that correspond to the recovered signals; and process the signal using the filter set to a particular configuration, of the one or more configurations, that corresponds to a lowest quantity of bit errors of the one or more quantities of bit error. | 12-27-2012 |
20110236018 | IN-BAND CONTROL PLANE AND MANAGEMENT FUNCTIONALITY IN OPTICAL LEVEL ONE VIRTUAL PRIVATE NETWORKS - A method performed by an optical node, operating as a first network edge device of an optical layer one virtual private network (L1VPN), includes generating, by a first module of the optical node, a first optical data frame, where the first optical data frame includes an L1VPN overhead, and where the L1VPN overhead includes a control plane communication field; generating, by a second module of the optical node, a first control plane message for a second network edge device of the optical L1VPN, where the second network edge device is connected to the first network edge device across a provider network via an optical L1VPN link; incorporating, by the first module, the first control plane message into the control plane communication field of the first optical data frame; and transmitting, by the first module, the first optical data frame to the second network edge device via the optical L1VPN link. | 09-29-2011 |
20110075549 | FAST PROTECTION PATH ACTIVATION USING CONTROL PLANE MESSAGES - A method, performed in a network that includes a group of nodes, includes identifying a path through a set of the nodes, where each node, in the set of nodes, has a data plane and a control plane; establishing a control plane tunnel, associated with the path, within the control plane of the nodes in the set of nodes; establishing a data plane tunnel, associated with the path, within the data plane of the nodes in the set of nodes, where the data plane tunnel is associated with the control plane tunnel and established through the same set of nodes; and transmitting a control message through the control plane tunnel to change a state of the data plane tunnel. | 03-31-2011 |
20100247037 | OPTICAL MODE COUPLER - An optical coupler includes a first waveguide configured to supply a first optical signal having a wavelength and a second waveguide. The first optical signal having a first mode. The first waveguide has a tapered portion being spaced from the second waveguide by a distance sufficient to facilitate evanescent coupling of the first optical signal from the first waveguide to the second waveguide. A first effective refractive index of the first waveguide at a location in the tapered portion being equal to a second effective refractive index at a location in the second waveguide. The first effective refractive index being associated with the first mode and the second effective refractive index being associated with a second mode of a second optical signal having the wavelength. The second mode having a different order than the first mode, and the second waveguide being configured to supply the second optical signal. | 09-30-2010 |
20100247036 | FLAT-TOP RESPONSE ARRAYED WAVEGUIDE GRATING - An optical system is disclosed. The optical system includes first and second waveguides, a first dispersive element, and a coupler. The first waveguide is configured to support a first mode and a second mode of an optical input signal. The second mode being of a higher order than the first mode. The second waveguide has an input and an output and is configured to receive a portion of the optical input signal. The first dispersive element is disposed along a length of one of the first or second waveguides. The first dispersive element including a waveguide segment configured to induce a frequency-dependent phase shift in one of the portions of the optical input signal. The coupler is configured to couple the portion of the optical input signal in the second waveguide and the portion optical input signal in the first waveguide into the first waveguide. The coupling excites the second mode of the first waveguide to create a multimode optical signal. | 09-30-2010 |
20100014861 | DUAL ASYNCHRONOUS MAPPING OF CLIENT SIGNALS OF ARBITRARY RATE - A network may include an ingress node that is configured to receive a client signal having a client rate that is one of a multiple different client rates, asynchronously map the client signal into a first frame of a first rate, asynchronously map the first frame into a second frame of a second rate, and output the second frame on the network; an intermediate node that is configured to receive the second frame, recover the first frame from the second frame, asynchronously map the first frame into a third frame of a third rate, and output the third frame on the network, where the intermediate node does not recover the client signal from the first frame; and an egress node that is configured to receive the third frame, recover the first frame from the third frame, recover the client signal from the first frame, and output the client signal. | 01-21-2010 |