Abstract: Systems, devices, and methods relate to a hybrid wireless access point (AP) which can support both single-channel mode and multi-channel mode at same time and within the same device. Uplink and/or downlink packets may be received by the hybrid AP, where the received packet may be same packet sent to different hybrid APs, and then each hybrid AP may decide to use these received packets for single-channel architecture (SCA), multi-channel architecture (MCA), or both. In SCA, the hybrid APs may communicate with each other to sync the SCA behavior.

Abstract: Systems, devices, and methods for two or more access points (APs), where each AP comprises: at least one LAN port for connection to the wired network; at least one LAN port for connection between at least one other AP; a processor having addressable memory, where the processor of a first AP of the two or more APs is configured to: select the first AP of the two or more APs as a primary AP; select the second AP of the two or more APs as a back-up AP; detect, via a trigger, a failure of the primary AP; and configure the second AP as the primary AP and the first AP as the back-up AP if the failure of the first AP is detected.

Abstract: Systems, devices, and methods for one or more hybrid access points, each hybrid access point comprising: an Ethernet port connecting the hybrid access point to one or more connected devices, where the Ethernet port is associated with an Ethernet-based media access control (MAC) address; one or more physical radios configured to transmit and receive wireless signals between the hybrid access point and one or more user devices; one or more virtual access points (VAPs) configured by the one or more physical radios, where the one or more VAPs comprise: at least one VAP configured to utilize a MAC layer of a multi-channel architecture (MCA); and at least one VAP configured to utilize a MAC layer of a channel blanket single-channel architecture (SCA); and a bridge connecting each VAP to the hybrid access point Ethernet port via the Ethernet-based MAC address.

Abstract: Systems, apparatuses, and devices for facilitating communication. An apparatus a first interface configured for coupling with a first pin pattern of an optical transceiver and a second interface configured for coupling with a second pin pattern of a printed circuit board. The apparatus is configured for communicatively coupling an optical transceiver having the first pin pattern with the second pin pattern of the printed circuit board.

Abstract: Some embodiments provide a system that includes an alert module, an event module, a notification trigger module, and a notification alert module. The alert module may be configured to receive a plurality of different sensor modality alerts. The event module may be configured to determine events based on the plurality of different sensor modality alerts. The notification trigger module may be configured to determine whether to cause transmission of notification alerts based on the determined events. The notification alert module may be configured to communicate notification alerts to a plurality of third parties based on the determination by the notification trigger module.

Abstract: Provided is a method including receiving data associated with at least one radiation detection sensor reading. The method also includes in response to the received data satisfying a certain condition, generating an event ticket; and assigning the event ticket to a first entity for processing.

Abstract: Systems, apparatuses, and methods described herein are configured for monitoring and managing a plurality of sensors. The plurality of sensors may be fixed, mobile, or a combination thereof. In some embodiments, the monitoring and management of the sensors is facilitated via a graphical user interface.

Abstract: Systems, apparatuses, and methods described herein are configured for monitoring and managing a plurality of sensors. The plurality of sensors may be fixed, mobile, or a combination thereof. In some embodiments, the monitoring and management of the sensors is facilitated via a graphical user interface.

Abstract: The present invention relates to systems and methods for controlling indicators on a device to achieve power and energy conservation. The systems and methods include enabling one or more indicators on the device and further include triggering the disablement of one or more of the indicators on the device based upon a disabling event. Upon detecting an enabling event, the systems and methods include re-enabling one or more of the disabled indicators.

Abstract: Apparatus and methods for reducing unwanted conducted noise generated by a DC load 17. Load 17 is powered by a voltage source 11. A current sense 13 senses pulse current Ifan flowing through the load 17. First converting means 14, 15, 16 converts the sensed pulse current Ifan to a correction voltage Vp. The correction voltage Vp is then converted to a correction current Ip, which offsets the deleterious effects of Ifan. The current Is flowing through the voltage source 11 equals Ifan plus the correction current Ip.

Abstract: Domain agnostic systems and methods for the capture, storage, and analysis of sensor readings are provided herein. In some embodiments, systems and methods comprise collecting and storing sensor readings obtained from disparate gauges operating in different domains. Sensor readings from different gauges occurring at different time intervals are uniformly aggregated to provide a consistent tabular representation of the data. In some embodiments, systems and methods analyze sensor readings from disparate gauges operating in different domains. Complex formulas may be used with the sensor readings from different gauges serving as input to those formulas. In some embodiments, systems and methods provide alerts on sensor readings from disparate gauges operating in different domains. Formulas of arbitrary complexity may be used to provide triggers that alert users of specific conditions being met as determined by the formulas used.

Abstract: The embodiments disclose a method for automatically communicating a command, received from a command server, to a set of nodes from a plurality of nodes on a network, executing the command on each node in the set of nodes and sending a response message from each node in the set of nodes to the command server indicating a type of executed action, wherein the set of nodes form a plurality of response messages.

Abstract: A method for automated calibration of an avalanche photodiode receiver includes measuring two values of avalanche photodiode biases at two successive times, measuring and comparing a bit error rate corresponding to each value. When the bit error rate of the second value is equal to or greater than the bit error rate of the first value, then a third value and a fourth value of avalanche photodiode bias closer together are measured. When the bit error rate of the fourth value is smaller than the bit error rate of the third value, two subsequent values as third value and fourth value are measured, and an optimum avalanche photodiode bias when the bit error rate of the fourth value is equal to the bit error rate of the third value is measured.

Abstract: A system and method for an Avalanche photo-diode (“APD”) optical receiver and laser system to adjust its performance during system operation without disturbing network traffic. Very small changes may be adaptively applied to some key portions of the system by controlling a set of main system parameters including Q-factor; Bit Error Rate (BER); histograms of “1” and “0” levels; input optical power; and laser output power. This adaptive routine may be performed during operation of the system to keep the main system parameters close to their optimum value. During adjustment, the system may be divided into separate portions. The adjustment of each portion may be independent of the other portions of the system. For the optical network system, optimization and priority of different portions may be assigned based on network channel architecture.

Abstract: A transit device and system that include a first link configured to receive a plurality of packets, and a second link communicatively coupled to the first link via a slow protocol filter. The plurality of packets include a first type of packet (e.g., data packets) and a second type of packet (e.g., slow protocol control packets). The transit device also includes a slow protocol filter that couples the first link to the second link, with the slow protocol filter being coupled to a local slow protocol client (e.g., local host CPU). Moreover, the slow protocol filter is configured to receive the plurality of packets from the first link, and to determine whether each of the plurality of packets is of the first type or the second type. The slow protocol filter also is configured to transmit each of the plurality of packets that are of the first type to the second link, and to transmit each of the plurality of packets that are the second type to the local slow protocol client.

Abstract: An optical communication system includes a first optical device including a transmission optical switch and a controller coupled to the transmission optical switch, and a second optical device coupled to the first optical device via each of a first fiber and a second fiber. The transmission optical switch is configured to operate in one of a first mode associated with the first fiber and a second mode associated with the second fiber based on control signals generated by the controller. Moreover, the controller is configured to perform a non-revertive switching operation on the transmission optical switch based on the satisfaction or the non-satisfaction of a predetermined condition or a plurality of predetermined conditions.

Abstract: A method and system for optimizing a response time of a monitoring loop with forward error correction. Characteristics of a fiber optic communications channel are adjusted based on the number of errors corrected in the FEC decoder. An adaptive BER is calculated much faster by using a signal from an FEC decoder, than by comparing input and output transmission. Thereby, the lag time in adjusting the transmission characteristics of the fiber optic channel is minimized and the overall performance of the system is improved.

Abstract: The optical signal multiplexer/demultiplexer of the invention is characterized by incorporating a bidirectional optical transceiver which is capable of using individual channels working in a transmitting and receiving modes simultaneously. The device consists of a number of optical prisms combined into a single module and provided with appropriate dichroic mirrors and interferrometric filters located on the outer surfaces of the prisms. According to one embodiment of the invention, the module consists of two sequentially arranged parallelogram prisms, a single-channel signal input/output unit with an optical collimator/focusator on one side of the prism module and a two-channel signal output/input unit with a respective optical collimator/focusator on the other side of the prism module.