Abstract: A drone may receive power from mobile base station equipment via an air-to-ground power feed during flight, which allows the drone to remain in flight for longer periods of time than relying on battery power alone. The air-to-ground power feed may be included in a tether that includes multiple air-to-ground power feeds or communication feeds. In some cases, the drone is powered by an on-board power system during takeoff and landing sequences to avoid damage to the tether or the drone and/or signal interference within the tether. In some cases, the drone may follow flight patterns during takeoff and landing sequences to avoid damage to the tether or the drone and/or signal interference within the tether.

Abstract: A drone includes a propulsion system, a processing unit, and a power system having a battery and a power connection port. The power system is configured to receive packetized electrical power over a tether including an air-to-ground power feed attachable to the power connection port. The power system is also configured to supply electrical power to the processing unit, the battery, and the propulsion system. The processing unit is configured to acknowledge receipt of the packetized electrical power. A power delivery system includes a packetized electrical power transmitter and a processing unit. The processing unit is configured to operate the packetized electrical power transmitter to transmit packets of electrical power over a power feed within a tether attached to a drone. The processing unit is also configured to monitor a communication channel within the tether for acknowledgements indicating the drone has received the transmitted packets of electrical power.

Abstract: A power appliance for a cell site is described. In particular, the appliance is a remote load loss compensator that boosts a voltage output from a power appliance housed in an equipment shelter of a cell site to a level suitable to compensate for conduction losses through a power supply line that feeds power output from the equipment shelter to one or more remote loads, such as a remote radio unit mounted atop an elevated structure. The remote load loss compensator includes a voltage converter and a controller configured to set an output voltage of the voltage converter to a level suitable to compensate for conduction losses in the power supply line.

Abstract: An accessory mounting device to mount an accessory to a weapon such as a firearm provides a base coupled to a mount member, and an attachment body coupled to the mount member. The mount member and attachment body define an interlocking mesh such that the mount member couples to the attachment body in any one of a plurality of positions for which a first component of the interlocking mesh engages with one of a plurality of second components of the interlocking mesh.

Abstract: An accessory mounting device to pivotably mount an accessory to a weapon such as a firearm provides recoil dampening and generally includes an accessory mount, a weapon attachment base, an arbor, and a detent mechanism. Advantageously, to flip or rotate the accessory mount through about 90 degrees between a first position above the base and a second position along a side of the base requires only grasping the accessory mount and rotating it from either of the positions through 90 degrees to the other position. No separate manual action to disengage any type of locking device is required, nor is any longitudinal or lateral translation of the mount involved. The function of providing stabilized, consistent location in each of the two positions, resistance to movement from each position, and manual movement of the mount that overcomes the resistance and rotates between the positions is provided by the detent mechanism.

Abstract: An accessory mounting device to pivotably mount an accessory to a weapon such as a firearm provides recoil dampening and generally may also include an accessory mount, a weapon attachment base, an arbor, and a detent mechanism. Advantageously, to flip or rotate the accessory mount through about 90 degrees between a first position above the base and a second position along a side of the base requires only grasping the accessory mount and rotating it from either of the positions through 90 degrees to the other position. No separate manual action to disengage any type of locking device is required, nor is any longitudinal or lateral translation of the mount involved. The function of providing stabilized, consistent location in each of the two positions, resistance to movement from each position, and manual movement of the mount that overcomes the resistance and rotates between the positions is provided by the detent mechanism.

Abstract: A system, apparatus, method, and manufacture for generating backup power in a wireless communications system such as a wireless communications service base station. The system includes a communications interface, a primary power interface, a generator, rectifiers, and a battery circuit. During normal operation, the communications interface is powered from the primary power interface. During a power outage, the communications interface is powered from either the generator or the battery circuit. The generator is cycled on and off during power outages to charge the battery circuit while conserving fuel. To decrease rectification loss, rectifiers are run near full load while rectifying the generator output.

Abstract: A power compensator for use in a cellular communication base station includes a voltage booster and an adaptive voltage boost controller. The voltage booster is coupled between a first port and a second port to apply a voltage boost to a power signal to generate a compensated power signal that is provided to a remote radio unit (RRU) of the base station. The adaptive voltage boost controller is configured to control the voltage boost applied by the voltage booster to compensate for a voltage loss across the power cable between the power compensator and the RRU. In operation, the adaptive voltage boost controller determines a value of the voltage boost to be applied by the voltage booster based on temperature data and electrical current sample data. The adaptive voltage boost controller then sends a control signal to the voltage booster to adjust the voltage boost based on the determined value.

Abstract: A system, apparatus, method, and manufacture for generating backup power in a wireless communications system such as a wireless communications service base station. The system includes a communications interface, a primary power interface, a generator, rectifiers, and a battery circuit. During normal operation, the communications interface is powered from the primary power interface. During a power outage, the communications interface is powered from either the generator or the battery circuit. The generator is cycled on and off during power outages to charge the battery circuit while conserving fuel. To decrease rectification loss, rectifiers are run near full load while rectifying the generator output.

Abstract: A power compensator for use in a cellular communication base station includes a voltage booster and an adaptive voltage boost controller. The voltage booster is coupled between a first port and a second port to apply a voltage boost to a power signal to generate a compensated power signal that is provided to a remote radio unit (RRU) of the base station. The adaptive voltage boost controller is configured to control the voltage boost applied by the voltage booster to compensate for a voltage loss across the power cable between the power compensator and the RRU. In operation, the adaptive voltage boost controller determines a value of the voltage boost to be applied by the voltage booster based on temperature data and electrical current sample data. The adaptive voltage boost controller then sends a control signal to the voltage booster to adjust the voltage boost based on the determined value.

Abstract: This disclosure describes techniques to identify and mitigate an effect of a power interruption that impacts the operation of Radio Frequency (RF) antennas associated with a telecommunications network. More specifically, an Adaptive Voltage Modification (AVM) controller is described that is configured to monitor and detect a change in voltage that occurs during a power transmission from a Direct Current (DC) power source to a Remote Radio Unit (RRU). A power interruption may include a power disruption or a power surge. The AVM controller may be configured to cause a potential transformer that is coupled between the DC power source and the RRU to incrementally step-up or step-down the voltage of a power transmission from the DC power source. In this way, the AVM controller may preemptively mitigate an impact of a power interruption on Quality of Service (QoS) parameters associated with signal data transmitted by the RF antennas.

Abstract: This disclosure describes techniques for identifying and mitigating a voltage loss in a power transmission to a Remote Radio Unit (RRU) associated with Radio Frequency (RF) antennas of a telecommunications network. More particularly, a Supplemental Voltage (SV) controller is described that is configured to monitor and detect a change in voltage that occurs during a power transmission from a primary Direct Current (DC) power source to the RRU and selectively cause a supplemental DC power source to transmit a supplemental voltage to the RF antennas. The SV controller may cause a supplemental DC power source to transmit a supplemental voltage to the RRU based on an empirical data analysis, sensory data analysis, or current environmental metadata. Further, the SV controller may determine whether the primary DC power source has suddenly ceased transmitting power to the RRU, and in doing so, cease transmission of a supplemental voltage to the RRU.

Abstract: Systems, apparatus, methods, and manufactures for conserving power in a communications system such as a communications service cell site or cell site. The methods include adjusting the RF coverage of the cell site antenna, selective control of the RF output transmit power, selective control of the communications bit rate, transfer of communications to other cell sites, adjustment of indicators such that mobile devices transfer communications to other cell sites, and reallocation of logical slots between radios in the cell site. In some examples, the cell site employs a power controller. The power controller may utilize a switching circuit to produce two different voltages from a single battery string during a commercial power failure with improved conversion efficiencies. In another example, a power controller may manage multiple rectifiers so that the rectifiers operate more efficiently, such as with approximately equal runtime and with regular testing.

Abstract: A system, apparatus, method, and manufacture for generating backup power in a wireless communications system such as a wireless communications service base station. The system includes a communications interface, a primary power interface, a generator, rectifiers, and a battery circuit. During normal operation, the communications interface is powered from the primary power interface. During a power outage, the communications interface is powered from either the generator or the battery circuit. The generator is cycled on and off during power outages to charge the battery circuit while conserving fuel. To decrease rectification loss, rectifiers are run near full load while rectifying the generator output.

Abstract: A system, apparatus, method, and manufacture for generating backup power in a wireless communications system such as a wireless communications service base station. The system includes a communications interface, a primary power interface, a generator, rectifiers, and a battery circuit. During normal operation, the communications interface is powered from the primary power interface. During a power outage, the communications interface is powered from either the generator or the battery circuit. The generator is cycled on and off during power outages to charge the battery circuit while conserving fuel. To decrease rectification loss, rectifiers are run near full load while rectifying the generator output.

Abstract: A simple and innovative process for manufacturing a high performance mechanical polarizing device is provided. The invention utilizes an inexpensive, high output production process where a transparent film substrate is coated with a non-transparent layer by deposition or other wet or dry method. Then a photoresist or a nano-imprint lithography process is used to overlay the non-transparent coated film with a pattern. The exposed non-transparent material is then removed by means of acid or base etching or the use of other mechanical or nano-technology removal methods. The photoresist is then removed and a protective layer may then be applied to the polarizer substrate. According to another embodiment, nano-imprinting techniques are used to prepare the polarizer substrate. The process may be automated in one or more embodiments, and lends itself to a high speed production manufacturing line, utilizing roll-to-roll, sheet fed or other methods of automated manufacturing.

Abstract: A method of operating a communication unit within a wireless communication network. The method comprises activating, by a controller, an auxiliary power unit that includes an auxiliary power generator and generating, by the auxiliary power unit, auxiliary power. The method further comprises routing the auxiliary power for use by the communication unit and based upon one or more factors, controlling, by the controller, operation of the auxiliary power unit.

Abstract: Systems, apparatus, methods, and manufactures for conserving power in a communications system such as a communications service cell site or cell site. The methods include adjusting the RF coverage of the cell site antenna, selective control of the RF output transmit power, selective control of the communications bit rate, transfer of communications to other cell sites, adjustment of indicators such that mobile devices transfer communications to other cell sites, and reallocation of logical slots between radios in the cell site. In some examples, the cell site employs a power controller. The power controller may utilize a switching circuit to produce two different voltages from a single battery string during a commercial power failure with improved conversion efficiencies. In another example, a power controller may manage multiple rectifiers so that the rectifiers operate more efficiently, such as with approximately equal runtime and with regular testing.

Abstract: Systems, apparatus, methods, and manufactures for conserving power in a communications system such as a communications service cell site or cell site. The methods include adjusting the RF coverage of the cell site antenna, selective control of the RF output transmit power, selective control of the communications bit rate, transfer of communications to other cell sites, adjustment of indicators such that mobile devices transfer communications to other cell sites, and reallocation of logical slots between radios in the cell site. In some examples, the cell site employs a power controller. The power controller may utilize a switching circuit to produce two different voltages from a single battery string during a commercial power failure with improved conversion efficiencies. In another example, a power controller may manage multiple rectifiers so that the rectifiers operate more efficiently, such as with approximately equal runtime and with regular testing.

Abstract: A system, apparatus, method, and manufacture for generating backup power in a wireless communications system such as a wireless communications service base station. The system includes a communications interface, a primary power interface, a generator, rectifiers, and a battery circuit. During normal operation, the communications interface is powered from the primary power interface. During a power outage, the communications interface is powered from either the generator or the battery circuit. The generator is cycled on and off during power outages to charge the battery circuit while conserving fuel. To decrease rectification loss, rectifiers are run near full load while rectifying the generator output.