Abstract: Boronic acid monomers, methods of making boronic acid monomer, and the like, are provided. Embodiments of the present disclosure are advantageous in that the boronic acid monomers are water soluble at a neutral pH, which is uncommon for boronic acids. As a result, the boronic acid monomers can be used in aqueous polymerization reactions with other hydrophilic monomers to yield polymers including boronic acids and esters.

Abstract: Boronic acid monomers, methods of making boronic acid monomer, and the like, are provided. Embodiments of the present disclosure are advantageous in that the boronic acid monomers are water soluble at a neutral pH, which is uncommon for boronic acids. As a result, the boronic acid monomers can be used in aqueous polymerization reactions with other hydrophilic monomers to yield polymers including boronic acids and esters.

Abstract: A radar system that uses a range walk compensation algorithm to reduce system losses resulting from moving targets. During the coherent integration of pulse radar systems, the conventional Fast Fourier Transform (FFT) for Doppler processing needs to change the input range bin number in accordance to the velocity of the target. The algorithm allows for configuration of Doppler groups to compute several Dopplers with one FFT. Each Doppler group has a transform Doppler that is close to the center of the group which will dictate the change of range bins for the input data to the FFT. As the range bins are changed, there are two input filter techniques: nearest bin select, and 2-tap filter. After range walk compensation processes all Doppler groups by FFT, the resultant output block has much higher coherent integration as compared to just a conventional FFT.

Abstract: A radar system that uses fast frequency hopping transmit waveform and filter bank receiver consisting of both analog and digital components. The waveform steps discrete frequency tones with short duration and modulates a continuous phase signal on each tone. The frequency hopping patterns are generated using pseudo-random permutation or low-collision method of anti-causal code shifting. To process waveform at radar receiver, a filter bank is used with squelching switches and controls to reduce distortion from strong signal into the receiver. Using the Strong Return Estimator, the timing of the strong signal is used to control the squelching switches.

Abstract: Boronic acid monomers, methods of making boronic acid monomer, and the like, are provided. Embodiments of the present disclosure are advantageous in that the boronic acid monomers are water soluble at a neutral pH, which is uncommon for boronic acids. As a result, the boronic acid monomers can be used in aqueous polymerization reactions with other hydrophilic monomers to yield polymers including boronic acids and esters.

Abstract: Boronic acid monomers, methods of making boronic acid monomer, and the like, are provided. Embodiments of the present disclosure are advantageous in that the boronic acid monomers are water soluble at a neutral pH, which is uncommon for boronic acids. As a result, the boronic acid monomers can be used in aqueous polymerization reactions with other hydrophilic monomers to yield polymers including boronic acids and esters.

Abstract: Boronic acid monomers, methods of making boronic acid monomer, and the like, are provided. Embodiments of the present disclosure are advantageous in that the boronic acid monomers are water soluble at a neutral pH, which is uncommon for boronic acids. As a result, the boronic acid monomers can be used in aqueous polymerization reactions with other hydrophilic monomers to yield polymers including boronic acids and esters.

Abstract: The present invention relates to a media processing system that comprises a bus for communicating digital signals thereon with a media processor connected to the bus, for processing signals supplied thereon. The system further has a display device connected to the bus for displaying digitized images thereon, received from the bus. The system has an audio transmitter connected to the bus, for wirelessly transmitting audio digital signals from the bus. The system further has a connectable memory for connecting to the bus and for supplying signals representing digitized images and audio digital signals to the bus. Finally the system has a receiver to receive encoded digitized images or audio digital signals for supplying the received signals to the bus for storage in the memory.

Abstract: Systems and methods are disclosed for wireless transmission and reception of data including processing and buffering features. According to one or more exemplary aspects, there is provided a wireless audio receiver for receiving a plurality of packets of encoded audio data. Moreover, the receiver includes at least one receiving component that receives the plurality of packets to generate a plurality of decoded signals, a decoding component that decodes the first packet of encoded data transmitted to produce decoded data, and a selecting component that identifies the mechanisms for receiving additional encoded data. Other exemplary embodiments may include one or more receiving components that processing data regarding antenna, frequencies and channels selected for transmission, as well as an audio component that receives the decoded signals and produces decoded audio signals.

Abstract: Systems and methods are disclosed for wireless transmission and reception of data including processing and buffering features. According to one or more exemplary aspects, there is provided a wireless audio receiver for receiving a plurality of packets of encoded audio data. Moreover, the receiver includes at least one receiving component that receives the plurality of packets to generate a plurality of decoded signals, a decoding component that decodes the first packet of encoded data transmitted to produce decoded data, and a selecting component that identifies the mechanisms for receiving additional encoded data. Other exemplary embodiments may include one or more receiving components that processing data regarding antenna, frequencies and channels selected for transmission, as well as an audio component that receives the decoded signals and produces decoded audio signals.

Abstract: The present invention relates to a media processing system that comprises a bus for communicating digital signals thereon with a media processor connected to the bus, for processing signals supplied thereon. The system further has a display device connected to the bus for displaying digitized images thereon, received from the bus. The system has an audio transmitter connected to the bus, for wirelessly transmitting audio digital signals from the bus. The system further has a connectable memory for connecting to the bus and for supplying signals representing digitized images and audio digital signals to the bus. Finally the system has a receiver to receive encoded digitized images or audio digital signals for supplying the received signals to the bus for storage in the memory.

Abstract: The present invention relates to a method of wirelessly transmitting and receiving audio digital signals of the type having a first plurality of blocks with each block having a second plurality of frames, with each frame having a third plurality of subframes, with each subframe having a preamble and a binary data. The method efficiently transmits and recomposes the digital audio signals by searching for the preamble associated with a subframe, which is the first subframe of a frame, with the frame being the first frame of a block, and then transmitting wirelessly only the binary data of each subframe, in each frame, in each block thereafter. In a preferred embodiment, the protocol for the transmission of data calls for each data packet that is transmitted to consist of 512 bytes. The data packet transmitted by the transmitter must be acknowledged by the transmission of an acknowledgement (ACK) packet from the receiver.

Abstract: The present invention relates to a wireless data system which has a transmitter including a transmission buffer. The transmitter is configured to transmit a plurality of packets of encoded data, wherein a level of the transmission buffer is encoded in one of the packets of encoded data. The system further has a wireless receiver for receiving the plurality of packets. The receiver has at least one receiving component that receives the plurality of packets to generate a plurality of decoded signals, wherein the at least one receiving component is configured to receive one of the packets of encoded data from the transmitter to determine the level of transmission buffer. The receiving component is further configured to store the plurality of packets received in a receive buffer, to determine the level of the receive buffer, and to calculate an aggregate buffer level from the transmission buffer and the receive buffer.

Abstract: The present invention relates to a method of wirelessly transmitting and receiving audio digital signals of the type having a first plurality of blocks with each block having a second plurality of frames, with each frame having a third plurality of subframes, with each subframe having a preamble and a binary data. The method efficiently transmits and recomposes the digital audio signals by searching for the preamble associated with a subframe, which is the first subframe of a frame, with the frame being the first frame of a block, and then transmitting wirelessly only the binary data of each subframe, in each frame, in each block thereafter. In a preferred embodiment, the protocol for the transmission of data calls for each data packet that is transmitted to consist of 512 bytes. The data packet transmitted by the transmitter must be acknowledged by the transmission of an acknowledgement (ACK) packet from the receiver.

Abstract: Systems and methods are disclosed for wireless transmission and reception of data including processing and buffering features. According to one or more exemplary aspects, there is provided a wireless audio receiver for receiving a plurality of packets of encoded audio data. Moreover, the receiver includes at least one receiving component that receives the plurality of packets to generate a plurality of decoded signals, a decoding component that decodes the first packet of encoded data transmitted to produce decoded data, and a selecting component that identifies the mechanisms for receiving additional encoded data. Other exemplary embodiments may include one or more receiving components that processing data regarding antenna, frequencies and channels selected for transmission, as well as an audio component that receives the decoded signals and produces decoded audio signals.

Abstract: Systems and methods are disclosed for wireless transmission and reception of data including processing and buffering features. According to one or more exemplary aspects, there is provided a wireless audio receiver for receiving a plurality of packets of encoded audio data. Moreover, the receiver includes at least one receiving component that receives the plurality of packets to generate a plurality of decoded signals, a decoding component that decodes the first packet of encoded data transmitted to produce decoded data, and a selecting component that identifies the mechanisms for receiving additional encoded data. Other exemplary embodiments may include one or more receiving components that processing data regarding antenna, frequencies and channels selected for transmission, as well as an audio component that receives the decoded signals and produces decoded audio signals.

Abstract: The present invention relates to a wireless data system which has a transmitter including a transmission buffer. The transmitter is configured to transmit a plurality of packets of encoded data, wherein a level of the transmission buffer is encoded in one of the packets of encoded data. The system further has a wireless receiver for receiving the plurality of packets. The receiver has at least one receiving component that receives the plurality of packets to generate a plurality of decoded signals, wherein the at least one receiving component is configured to receive one of the packets of encoded data from the transmitter to determine the level of transmission buffer. The receiving component is further configured to store the plurality of packets received in a receive buffer, to determine the level of the receive buffer, and to calculate an aggregate buffer level from the transmission buffer and the receive buffer.