Abstract: Digital holographic microscopy and related image processing techniques are described. A hologram captured in an image frame is split into different depths while a new hologram is being captured. Image slices of the hologram are determined and using free space impulse responses that are pre-calculated at a different precision than processing operations using the holographic data. Each computation is calculated in parallel based on the number of available processing cores and threads. The image slices are combined into a 2D array or 3D array to permit further processing of the combined array to count and size particles in the image frame. The reconstructed hologram is displayed at a subsequent image frame than that used to capture the hologram.

Abstract: The Internet can be configured to provide communications to a large number of Internet-of-Things (IoT) devices. Devices can be designed to address the need for network layers, from central servers, through gateways, down to edge devices, to grow unhindered, to discover and make accessible connected resources, and to support the ability to hide and compartmentalize connected resources. Network protocols can be part of the fabric supporting human accessible services that operate regardless of location, time, or space. Innovations can include service delivery and associated infrastructure, such as hardware and software. Services may be provided in accordance with specified Quality of Service (QoS) terms. The use of IoT devices and networks can be included in a heterogeneous network of connectivity including wired and wireless technologies.

Abstract: The Internet can be configured to provide communications to a large number of Internet-of-Things (IoT) devices. Devices can be designed to address the need for network layers, from central servers, through gateways, down to edge devices, to grow unhindered, to discover and make accessible connected resources, and to support the ability to hide and compartmentalize connected resources. Network protocols can be part of the fabric supporting human accessible services that operate regardless of location, time, or space. Innovations can include service delivery and associated infrastructure, such as hardware and software. Services may be provided in accordance with specified Quality of Service (QoS) terms. The use of IoT devices and networks can be included in a heterogeneous network of connectivity including wired and wireless technologies.

Abstract: A split structure design for an internet of things (IoT) device including a control IoT device (CID) and a sensor IoT device (SID). An example of an apparatus provides a CID including a power transmitter to power a SID through a barrier and a control data transceiver to communicate with the SID through the barrier. The CID includes a power adjustor to increase a power transmission to the SID in steps, and an intermodule communicator to determine if communications have been established with the sensor IoT, and, if not, instruct the power adjustor to increase the power transmission to the SID by a step.

Abstract: Digital holographic microscopy and related image processing techniques are described. A hologram captured in an image frame is split into different depths while a new hologram is being captured. Image slices of the hologram are determined and using free space impulse responses that are pre-calculated at a different precision than processing operations using the holographic data. Each computation is calculated in parallel based on the number of available processing cores and threads. The image slices are combined into a 2D array or 3D array to permit further processing of the combined array to count and size particles in the image frame. The reconstructed hologram is displayed at a subsequent image frame than that used to capture the hologram.

Abstract: The Internet can be configured to provide communications to a large number of Internet-of-Things (IoT) devices. Devices can be designed to address the need for network layers, from central servers, through gateways, down to edge devices, to grow unhindered, to discover and make accessible connected resources, and to support the ability to hide and compartmentalize connected resources. Network protocols can be part of the fabric supporting human accessible services that operate regardless of location, time, or space. Innovations can include service delivery and associated infrastructure, such as hardware and software. Services may be provided in accordance with specified Quality of Service (QoS) terms. The use of IoT devices and networks can be included in a heterogeneous network of connectivity including wired and wireless technologies.

Abstract: A sound source localization apparatus configured to identify a location for an active sound object within a defined physical space is described. The sound source localization apparatus may include an acoustic component, a thermal component, and an analysis component. The acoustic component determines an approximate location for at least one sound object within the defined physical space. The thermal component determines an approximate location for at least one thermal object within the defined physical space. The analysis component identifies the active sound object when the approximate locations for at least one acoustic object and at least one thermal object match. Other embodiments are described and claimed.

Abstract: Technologies for monitoring a characteristic of a monitored system include determining a measured value of the primary characteristic of the monitored system sensed by a primary sensor and a measured value of the secondary characteristic of the monitored system sensed by a secondary sensor, and predicating a predicted value of the primary characteristic based on the measured value of the secondary characteristic. The measured and predicted values of the primary characteristic are used to determine whether the primary sensor is properly functioning.

Abstract: Technologies for monitoring a characteristic of a monitored system include determining a measured value of the primary characteristic of the monitored system sensed by a primary sensor and a measured value of the secondary characteristic of the monitored system sensed by a secondary sensor, and predicating a predicted value of the primary characteristic based on the measured value of the secondary characteristic. The measured and predicted values of the primary characteristic are used to determine whether the primary sensor is properly functioning.

Abstract: An audio signal processing system removes at least a portion of a noise component from a number of audio input signals generated by a number of closely proximate agents within an input signal source location. The availability of each audio input signal and the geographically proximate location of each of the agents creating an audio input signal facilitates the real-time or near real-time reduction in ambient noise level in each of the audio input signals using a Blind Sound Source Separation (BSSS) technique.

Abstract: Ultrasonic location systems are provided. These ultrasonic location systems include two or more wave transmitters, two or more wave receivers, and a mapping component that controls the operation of the transmitters and the receivers. The mapping component relies on collaborative operation of multiple transmitters and multiple phased-array receivers where each of the transmitters emits a short burst of sound wave in a pre-defined sequence and after every burst all phased-array receivers detect the wave reflected from surrounding objects. The mapping component uses the position of the transmitters, the position of the receivers, the time of transmission, the time of reception, and the phase shift of the waves to calculate a time of flight and a direction of arrival for the reflections. The mapping component uses triangulation to determine a distance between any physical objects acting as sources of reflection and one or more physical objects having a recorded position relative to the receivers.

Abstract: Embodiments of a system and method for removing speech by a user from audio frames are generally described herein. A method may include receiving a plurality of frames of audio data, extracting a set of frames of the plurality of frames, the set of frames including speech by a user with a set of remaining frames in the plurality of frames not in the set of frames, suppressing the speech by the user from the set of frames using a trained model to create a speech-suppressed set of frames, and recompiling the plurality of frames using the speech-suppressed set of frames and the set of remaining frames.

Abstract: A split structure design for an internet of things (IoT) device including a control IoT device (CID) and a sensor IoT device (SID). An example of an apparatus provides a CID including a power transmitter to power a SID through a barrier and a control data transceiver to communicate with the SID through the barrier. The CID includes a power adjustor to increase a power transmission to the SID in steps, and an intermodule communicator to determine if communications have been established with the sensor IoT, and, if not, instruct the power adjustor to increase the power transmission to the SID by a step.

Abstract: A multimodal object tracking apparatus configured to identify a location for a target object within a defined physical space is described. The object tracking apparatus may include an acoustic component, a thermal component, and an analysis component. The acoustic component determines an approximate location for at least one sound object within the defined physical space. The thermal component determines an approximate location for at least one thermal object within the defined physical space. The analysis component identifies the target object when the approximate locations for at least one acoustic object and at least one thermal object match. Other embodiments are described and claimed.

Abstract: An audio signal processing system removes at least a portion of a noise component from a number of audio input signals generated by a number of closely proximate agents within an input signal source location. The availability of each audio input signal and the geographically proximate location of each of the agents creating an audio input signal facilitates the real-time or near real-time reduction in ambient noise level in each of the audio input signals using a Blind Sound Source Separation (BSSS) technique.

Abstract: A sound source localization apparatus configured to identify a location for an active sound object within a defined physical space is described. The sound source localization apparatus may include an acoustic component, a thermal component, and an analysis component. The acoustic component determines an approximate location for at least one sound object within the defined physical space. The thermal component determines an approximate location for at least one thermal object within the defined physical space. The analysis component identifies the active sound object when the approximate locations for at least one acoustic object and at least one thermal object match. Other embodiments are described and claimed.

Abstract: Embodiments of a system and method for removing speech by a user from audio frames are generally described herein. A method may include receiving a plurality of frames of audio data, extracting a set of frames of the plurality of frames, the set of frames including speech by a user with a set of remaining frames in the plurality of frames not in the set of frames, suppressing the speech by the user from the set of frames using a trained model to create a speech-suppressed set of frames, and recompiling the plurality of frames using the speech-suppressed set of frames and the set of remaining frames.

Abstract: A method for controlling laser scanning microscopy of a probe comprising at least one cell is disclosed. The method comprises the steps of acquiring at least one initial image of the probe and identifying at least one cell within an initial probe image. Using a pre-defined grammar, a first set of scanning mode parameters for monitoring the cell(s); a first set of trigger parameters including at least one physiological parameter defining an event in the cell(s); and a second set of scanning mode parameters for monitoring at least one cell of the probe after an occurrence of the event is defined. A successive set of probe images acquired according to the first set of scanning mode parameters is provided and processed to determine if the event has occurred. Responsive to the event occurring, microscope modality is changed to the second set of scanning mode parameters.

Abstract: Circuits perform row-by-row matrix generation for encoding and decoding of data blocks. They perform fast algebraic generation of high performance low density parity check (LDPC) matrices suitable for use in a wide range of error correction coding and decoding (ECC) applications. Circuit operation is based on a mathematical Cyclic Ring method that enables matrices of any size to be generated from a simple set of initial parameters, based on user-defined performance requirements. The main steps for generating a parity check matrix (H) are selection of an RG matrix structure, selection of Group Ring elements, generating the sub matrices for the RG matrix by a row filling scheme, generating the RG matrix by a cyclic arrangement of the sub matrices, and generating the parity-check matrix by deleting suitably chosen columns from the RG matrix to achieve the desired performance and then transposing the matrix.