Abstract: Provided herein are embodiments of an aversive cable. The cable includes a cable core comprising a longitudinal axis, a cable jacket surrounding the cable core along the longitudinal axis, and at least one sacrificial lobe. The cable jacket has an outer surface, and each of the at least one sacrificial lobe extends longitudinally along at least a portion of cable jacket and radially outward from the outer surface of the cable jacket. The cable jacket and the at least one sacrificial lobe include an aversive material. In embodiments, the sacrificial lobes are included on a cable sheath instead of the cable jacket, and the cable sheath surrounds the cable jacket without being bonded to the cable jacket.

Abstract: A device receives an AOI selection that indicates a geographic area. The device accesses AOI device location data for the AOI that indicates locations of plural devices detected within the AOI. The device sets a device penetration rate configuration based on at least one characteristic of the AOI. The device determines respective weighting factors for each of the plural devices detected within the AOI based on one or more device penetration rates corresponding to the set device penetration rate configuration. Each of the one or more device penetration rates indicating, for a corresponding geographic region, a number of devices with home locations within the geographic region divided by a population of the geographic region. The device generates an estimate of a number of users in the AOI based on the plural devices detected within the AOI, and the respective weighting factors. The device transmits the estimate to a client device.

Abstract: Provided herein are embodiments of an aversive cable. The cable includes a cable core comprising a longitudinal axis, a cable jacket surrounding the cable core along the longitudinal axis, and at least one sacrificial lobe. The cable jacket has an outer surface, and each of the at least one sacrificial lobe extends longitudinally along at least a portion of cable jacket and radially outward from the outer surface of the cable jacket. The cable jacket and the at least one sacrificial lobe include an aversive material. In embodiments, the sacrificial lobes are included on a cable sheath instead of the cable jacket, and the cable sheath surrounds the cable jacket without being bonded to the cable jacket.

Abstract: A coaxial cable includes: a center conductor; a dielectric layer circumferentially surrounding the center conductor; and an outer conductor circumferentially surrounding the dielectric layer. The dielectric layer comprises an inner sleeve that circumferentially overlies the center conductor and an outer sleeve that circumferentially overlies the inner conductor. The outer sleeve contacts the inner sleeve to form a plurality of longitudinally-spaced seams to create a plurality of sealed segments along a longitudinal axis of the cable.

Abstract: A method of manufacturing a coaxial cable includes: providing an intermediate construction for a coaxial cable comprising an inner conductor, a dielectric layer circumferentially surrounding the inner conductor, and a smooth outer conductor circumferentially surrounding and adhered to the dielectric layer; and impressing corrugations into the outer conductor and corresponding protrusions in the dielectric layer.

Abstract: A coaxial cable includes: a center conductor; a dielectric layer circumferentially surrounding the center conductor; and an outer conductor circumferentially surrounding the dielectric layer. The dielectric layer comprises an inner sleeve that circumferentially overlies the center conductor and an outer sleeve that circumferentially overlies the inner conductor. The outer sleeve contacts the inner sleeve to form a plurality of longitudinally-spaced seams to create a plurality of sealed segments along a longitudinal axis of the cable.

Abstract: A cable reduces loop inductance by changing the cross-sectional shape of the conductive elements of power supply and return conductors to something other than the traditional circular cross sectional shape, e.g., to a thin generally rectangular shape. The power supply and return conductors are also controlled in placement along the length of the cable, so that mutual inductance is maximized within a given power supply circuit, and minimized between the given power supply circuit and other power supply circuits within the cable. The return power supply conductor may optionally be sized for multiple power supply circuits, which may further reduce loop inductance and reduce crosstalk noise between different power supply circuits within a common cable. The power supply and return conductors may be part of a hybrid cable used to power and communicate with plural remote radio units proximate a top of a tower.

Abstract: A stripline RF transmission cable has a flat inner conductor surrounded by a dielectric layer that is surrounded by an outer conductor. A jacket with an attachment feature surrounds the outer conductor. The attachment feature may be a fin aligned parallel or normal to the inner conductor. The attachment feature may be continuous or periodic along a longitudinal extent of the cable. The attachment feature may include male and female portions dimensioned to couple with one another, enabling adjacent cables to be attached to one another.

Abstract: A method for manufacturing an electrical cable includes dividing a tube into a plurality of sectors by passage across a sectoring device, gathering the sectors into a stack by passage of the sectors through a gathering device, and surrounding the stack with an insulating layer. Additional strip features may be applied by application of one or more strip conditioners. Alternatively, strips may be supplied on individual reels for gathering or provided in a multi-end reel already stacked. Where a multi-end reel is provided, length differentials within the stack as it is unwound may be compensated for by application of a stretcher.

Abstract: A cable reduces loop inductance by changing the cross-sectional shape of the conductive elements of power supply and return conductors to something other than the traditional circular cross sectional shape, e.g., to a thin generally rectangular shape. The power supply and return conductors are also controlled in placement along the length of the cable, so that mutual inductance is maximized within a given power supply circuit, and minimized between the given power supply circuit and other power supply circuits within the cable. The return power supply conductor may optionally be sized for multiple power supply circuits, which may further reduce loop inductance and reduce crosstalk noise between different power supply circuits within a common cable. The power supply and return conductors may be part of a hybrid cable used to power and communicate with plural remote radio units proximate a top of a tower.

Abstract: A method for manufacturing an electrical cable includes dividing a tube into a plurality of sectors by passage across a sectoring device, gathering the sectors into a stack by passage of the sectors through a gathering device, and surrounding the stack with an insulating layer. Additional strip features may be applied by application of one or more strip conditioners. Alternatively, strips may be supplied on individual reels for gathering or provided in a multi-end reel already stacked. Where a multi-end reel is provided, length differentials within the stack as it is unwound may be compensated for by application of a stretcher.

Abstract: A system and method for collecting storing, distributing and tracking digital coupons. The system and method include a platform/interface of a computing system for a plurality of businesses to submit digital coupons to a central coupon database of an application programming interface, and a platform/interface for consumers to create a user account with a user coupon database. The system and method further include a performance tracking database that stores information regarding coupons that are selected and redeemed by each user of the computing system.

Abstract: A stripline RF transmission cable has a flat inner conductor surrounded by a dielectric layer that is surrounded by an outer conductor. A jacket with an attachment feature surrounds the outer conductor. The attachment feature may be a fin aligned parallel or normal to the inner conductor. The attachment feature may be continuous or periodic along a longitudinal extent of the cable. The attachment feature may include male and female portions dimensioned to couple with one another, enabling adjacent cables to be attached to one another.

Abstract: A fiber optic cable includes: a plurality of optical fibers; a tube circumferentially surrounding the optical fibers, the tube being formed of a first polymeric material; an armor circumferentially surrounding and fixed relative to the tube, the armor being formed of a metallic material; and a jacket circumferentially surrounding the armor, the jacket being formed of a second polymeric material. In this configuration, the cable can provide the requisite mechanical, electrical, handling and connectorizing properties for use in applications such as pavement crossings.

Abstract: A method of making a coaxial cable includes forming a conductive tube and setting a settable material therein to define an inner conductor. Forming may include advancing a conductive strip and bending it into a tube having a longitudinal seam. The settable material may be dispensed onto the conductive strip continuously with the forming. Alternately, the settable material may be dispensed onto the conductive strip prior to advancing. The dispensing may use a puller cord as the settable material or carrying some or all of the settable material. The method may further include forming a dielectric layer surrounding the inner conductor, and forming an outer conductor surrounding the dielectric layer.

Abstract: The present invention is a flexible low loss coaxial cable comprising a cylindrical plastic rod, an inner conductor surrounding the plastic rod, a dielectric layer surrounding the inner conductor, and a tubular metallic sheath closely surrounding the dielectric layer. The coaxial cable can further include a protective polymer jacket surrounding the sheath. The cylindrical plastic rod supports the inner conductor in bending and can be formed around a central structural member. The present invention also includes a method of making flexible coaxial cable.

Abstract: A fiber optic cable includes: a plurality of optical fibers; a tube circumferentially surrounding the optical fibers, the tube being formed of a first polymeric material; an armor circumferentially surrounding and fixed relative to the tube, the armor being formed of a metallic material; and a jacket circumferentially surrounding the armor, the jacket being formed of a second polymeric material. In this configuration, the cable can provide the requisite mechanical, electrical, handling and connectorizing properties for use in applications such as pavement crossings.

Abstract: A method of making a coaxial cable includes forming a conductive tube and setting a settable material therein to define an inner conductor. Forming may include advancing a conductive strip and bending it into a tube having a longitudinal seam. The settable material may be dispensed onto the conductive strip continuously with the forming. Alternately, the settable material may be dispensed onto the conductive strip prior to advancing. The dispensing may use a puller cord as the settable material or carrying some or all of the settable material. The method may further include forming a dielectric layer surrounding the inner conductor, and forming an outer conductor surrounding the dielectric layer.

Abstract: A flexible low loss coaxial cable comprises a cylindrical plastic rod, an inner conductor surrounding the plastic rod, a dielectric layer surrounding the inner conductor, and a tubular metallic sheath closely surrounding the dielectric layer. The coaxial cable can further include a protective polymer jacket surrounding the sheath. The cylindrical plastic rod supports the inner conductor in bending and can be formed around a central structural member. The present invention also includes a method of making flexible coaxial cable.

Abstract: The present invention provides a coaxial cable having increasing moisture absorbency to remove moisture present in the cable and to prevent corrosion of the conductors in the cable. The coaxial cable of the invention includes an inner conductive tube, a moisture-absorbent material within the inner conductive tube, a dielectric surrounding the inner conductive tube, and a tubular metallic outer sheath surrounding the dielectric. The present invention further includes a method of making a coaxial cable that is capable of absorbing moisture that is present in the cable.