Abstract: Aspects of the present disclosure include a detection system including a base device including a power source configured to provide electrical energy to a plurality of edge nodes of a sensor network and a base data link configured to transmit a sensor interrogation signal to at least one of the plurality of edge nodes in the detection system and receive reporting information from at least one of the plurality of edge nodes, and the plurality of edge nodes sequentially coupled within the sensor network, wherein each edge node includes an edge data link configured to receive at least a portion of the electrical energy and the sensor interrogation signal, relay the at least a portion of the electrical energy and the sensor interrogation signal to a next edge node of the plurality of edge nodes, and transmit to the base device, in response to the sensor interrogation signal, the reporting information including sensor information associated with the edge node or a no selection match indication.

Abstract: Aspects of the present disclosure are directed to a measurement module for measurement of a multi-electrode resistive sensing element with improved noise performance and accuracy. In some embodiments, stimulation to the sensing element is provided by a current path that originates from a signal source, through a switch block, through a pair of terminals, and ending at a reference node such as ground. An analog-to-digital converter (ADC) is coupled directly to one or both of the terminals to digitize a voltage. The ADC is coupled to terminals on the sensing element to measure a sensed voltage signal before the sensed signal goes through the switch block. As a result, the measured voltage signal may be free of noise that could be picked up from passing through the switch block, and accuracy of the resistance measurements on the sensing element can be improved.

Abstract: Systems and methods are provided for wirelessly communicating with multiple sensors. In particular, a multi-sensor platform is provided that acts as an intermediary node and can communicate with multiple integrity sensors. The integrity sensors are each coupled via a wired connection to the multi-sensor platform, and the multi-sensor platform is powered wirelessly by a radiofrequency transmitter. The radiofrequency transmitter can receive data from multiple sensors via one node, the multi-sensor platform, thus allowing the radiofrequency transmitter to have a static transmission beam.

Abstract: A circuit may include a detector, an approximator, a look-up table, a scaler, and an integrator. The detector may generate a first difference signal and a second different signal based on an input and an output. The approximator may generate, using a one's complement operation, an index based on approximated modulus values of the first difference signal and the second difference signal. The look-up table may select one of a plurality of scaling factors based upon the index. The scaler may adjust the first difference signal and the second difference signal based on the selected scaling factor. The integrator may generate the output based on the adjusted first difference signal and the adjusted second difference signal.

Abstract: A circuit may include a detector, an approximator, a look-up table, a scaler, and an integrator. The detector may generate a first difference signal and a second different signal based on an input and an output. The approximator may generate, using a one's complement operation, an index based on approximated modulus values of the first difference signal and the second difference signal. The look-up table may select one of a plurality of scaling factors based upon the index. The scaler may adjust the first difference signal and the second difference signal based on the selected scaling factor. The integrator may generate the output based on the adjusted first difference signal and the adjusted second difference signal.

Abstract: A channel adaptive iterative turbo decoder for computing with MAP decoders a set of branch metrics for a window of received data, computing the forward and reverse recursive path state metrics and computing from the forward and reverse recursive path state metrics the log likelihood ratio for 1 and 0 and interleaving the decision bits; and identifying those MAP decoder decision bits which are non-convergent, computing a set of branch metrics for the received data, computing from the forward and reverse recursive path state metrics the log likelihood ratio (LLR) for 1 and 0 for each non-converged decision bit and interleaving the non-convergent decision bits.

Abstract: Video decoding with video enhancement using direct contrast enhancement in the spatial domain including transforming the decoded intramacroblock output to a matrix of spatial domain coefficients; multiplying the spatial domain coefficients with the corresponding intramacroblock enhancement matrix elements of an intramacroblock enhancement matrix to provide enhanced spatial coefficients; transforming said enhanced spatial coefficients to the temporal domain to generate an enhanced decoded intramacroblock; multiplying the spatial domain intermacroblock coefficients from the entropy decoder of the video decoder with the corresponding intermacroblock enhancement matrix elements of an intermacroblock enhancement matrix to provide enhanced spatial coefficients, and transforming the enhanced spatial coefficients to generate enhanced decoded residual coefficients.

Abstract: A method of spatial domain video enhancement/up-scaling including transforming the video input from the temporal domain to a K×K matrix of spatial domain coefficients; multiplying each spatial domain coefficient by corresponding elements of a K×K enhancement matrix to obtain enhanced spatial domain coefficients; depositing the enhanced spatial domain coefficients in the upper left K×K corner of a zero padded 2K×2K inverse transform matrix and inversely transforming them to scale the enhanced spatial domain coefficients and convert them back to video output temporal domain elements and a method of spatial domain video enhancement/down-scaling including transforming the video input from the temporal domain to a 2K×2K matrix of spatial domain coefficients; multiplying the upper left K×K corner of the 2K×2K matrix of spatial domain coefficients by the corresponding elements of a K×K enhancement matrix to obtain enhanced spatial domain coefficients; inversely transforming the K×K enhanced spatial domain coefficien

Abstract: Simultaneously decoding one or more variable length code symbols including storing in a bit FIFO at least a portion of a variable length coded bit stream; storing a succession of extracted bit fields of predetermined bit length from the variable length coded bit stream in the bit FIFO; defining at least one inspection field in the extracted bit field, each inspection field identifying at least one variable length code symbol; and storing in look-up table a decode value uniquely addressable by each bit combination of the inspection field for reading out the one or more decode values corresponding to the unique address defined by the inspection field.

Abstract: A channel adaptive iterative turbo decoder for computing with MAP decoders a set of branch metrics for a window of received data, computing the forward and reverse recursive path state metrics and computing from the forward and reverse recursive path state metrics the log likelihood ratio for 1 and 0 and interleaving the decision bits; and identifying those MAP decoder decision bits which are non-convergent, computing a set of branch metrics for the received data, computing from the forward and reverse recursive path state metrics the log likelihood ratio (LLR) for 1 and 0 for each non-converged decision bit and interleaving the non-convergent decision bits.

Abstract: A method and apparatus for direct mapping in a compute unit having an internal random access memory the primary operational sequences of an algorithm to related function including storing in an internal random access memory at least one predetermined direct mapped function value for each primary operational sequence of an algorithm; holding in an input data register the address in the random access memory of at least one mapped function value for a selected primary operational sequence of the algorithm and holding in an output register the at least one mapped function value for the selected primary operational sequence of the algorithm read out of the random access memory.

Abstract: Video decoding with video enhancement using direct contrast enhancement in the spatial domain including transforming the decoded intramacroblock output to a matrix of spatial domain coefficients; multiplying the spatial domain coefficients with the corresponding intramacroblock enhancement matrix elements of an intramacroblock enhancement matrix to provide enhanced spatial coefficients; transforming said enhanced spatial coefficients to the temporal domain to generate an enhanced decoded intramacroblock; multiplying the spatial domain intermacroblock coefficients from the entropy decoder of the video decoder with the corresponding intermacroblock enhancement matrix elements of an intermacroblock enhancement matrix to provide enhanced spatial coefficients, and transforming the enhanced spatial coefficients to generate enhanced decoded residual coefficients.

Abstract: A method of spatial domain video enhancement/up-scaling including transforming the video input from the temporal domain to a K×K matrix of spatial domain coefficients; multiplying each spatial domain coefficient by corresponding elements of a K×K enhancement matrix to obtain enhanced spatial domain coefficients; depositing the enhanced spatial domain coefficients in the upper left K×K corner of a zero padded 2K×2K inverse transform matrix and inversely transforming them to scale the enhanced spatial domain coefficients and convert them back to video output temporal domain elements and a method of spatial domain video enhancement/down-scaling including transforming the video input from the temporal domain to a 2K×2K matrix of spatial domain coefficients; multiplying the upper left K×K corner of the 2K×2K matrix of spatial domain coefficients by the corresponding elements of a K×K enhancement matrix to obtain enhanced spatial domain coefficients; inversely transforming the K×K enhanced spatial domain coefficien

Abstract: A method and apparatus for direct mapping in a compute unit having an internal random access memory the primary operational sequences of an algorithm to related function including storing in an internal random access memory at least one predetermined direct mapped function value for each primary operational sequence of an algorithm; holding in an input data register the address in the random access memory of at least one mapped function value for a selected primary operational sequence of the algorithm and holding in an output register the at least one mapped function value for the selected primary operational sequence of the algorithm read out of the random access memory.

Abstract: Simultaneously decoding one or more variable length code symbols including storing in a bit FIFO at least a portion of a variable length coded bit stream; storing a succession of extracted bit fields of predetermined bit length from the variable length coded bit stream in the bit FIFO; defining at least one inspection field in the extracted bit field, each inspection field identifying at least one variable length code symbol; and storing in look-up table a decode value uniquely addressable by each bit combination of the inspection field for reading out the one or more decode values corresponding to the unique address defined by the inspection field.