Abstract: A high-integrity opaque-inset panel envelope includes a front panel formed from a printable material, one or more apertures being defined therethrough, one or more flaps extending from the edges of the front panel, and one or more opaque inset panels/labels disposed on an inner surface of the front panel to cover the one or more apertures. Opaque inset panels can have an optical brightness about 1-6% greater than the optical brightness of the printable material. The envelope can be formed by removing portions of a printable material to form one or more flaps about a front panel and one or more apertures through the front panel and disposing one or more opaque inset panels to an inner surface of the front panel, such that the one or more opaque inset panels covers the one or more apertures.

Abstract: An apparatus to couple an inset panel to a back surface of a front panel of an envelope blank such that the inset panel substantially seals a window through the front panel of the envelope blank and is visible through the window of the front panel of the envelope blank, wherein a front surface of the front panel of the envelope blank has a first optical brightness, and wherein a first surface of the inset panel that is visible through the window has a second optical brightness that is more than or equal to about 1% greater than the first optical brightness.

Abstract: A high-integrity opaque-inset panel envelope includes a front panel formed from a printable material, one or more apertures being defined therethrough, one or more flaps extending from the edges of the front panel, and one or more opaque inset panels/labels disposed on an inner surface of the front panel to cover the one or more apertures. Opaque inset panels can have an optical brightness about 1-6% greater than the optical brightness of the printable material. The envelope can be formed by removing portions of a printable material to form one or more flaps about a front panel and one or more apertures through the front panel and disposing one or more opaque inset panels to an inner surface of the front panel, such that the one or more opaque inset panels covers the one or more apertures.

Abstract: A high-integrity opaque-inset panel envelope includes a front panel formed from a printable material, one or more apertures being defined therethrough, one or more flaps extending from the edges of the front panel, and one or more opaque inset panels/labels disposed on an inner surface of the front panel to cover the one or more apertures. Opaque inset panels can have an optical brightness about 1-6% greater than the optical brightness of the printable material. The envelope can be formed by removing portions of a printable material to form one or more flaps about a front panel and one or more apertures through the front panel and disposing one or more opaque inset panels to an inner surface of the front panel, such that the one or more opaque inset panels covers the one or more apertures.

Abstract: A high-integrity opaque-inset panel envelope includes a front panel formed from a printable material, one or more apertures being defined therethrough, one or more flaps extending from the edges of the front panel, and one or more opaque inset panels/labels disposed on an inner surface of the front panel to cover the one or more apertures. Opaque inset panels can have an optical brightness about 1-6% greater than the optical brightness of the printable material. The envelope can be formed by removing portions of a printable material to form one or more flaps about a front panel and one or more apertures through the front panel and disposing one or more opaque inset panels to an inner surface of the front panel, such that the one or more opaque inset panels covers the one or more apertures.

Abstract: A high-integrity opaque-inset panel envelope includes a front panel formed from a printable material, one or more apertures being defined therethrough, one or more flaps extending from the edges of the front panel, and one or more opaque inset panels/labels disposed on an inner surface of the front panel to cover the one or more apertures. Opaque inset panels can have an optical brightness about 1-6% greater than the optical brightness of the printable material. The envelope can be formed by removing portions of a printable material to form one or more flaps about a front panel and one or more apertures through the front panel and disposing one or more opaque inset panels to an inner surface of the front panel, such that the one or more opaque inset panels covers the one or more apertures.

Abstract: A high-integrity opaque-inset panel envelope includes a front panel formed from a printable material, one or more apertures being defined therethrough, one or more flaps extending from the edges of the front panel, and one or more opaque inset panels/labels disposed on an inner surface of the front panel to cover the one or more apertures. Opaque inset panels can have an optical brightness about 1-6% greater than the optical brightness of the printable material. The envelope can be formed by removing portions of a printable material to form one or more flaps about a front panel and one or more apertures through the front panel and disposing one or more opaque inset panels to an inner surface of the front panel, such that the one or more opaque inset panels covers the one or more apertures.

Abstract: Aspects of the present disclosure generally relate to systems and methods for facilitating optimization of mobile application testing. In one embodiment, a mobile application testing system (MATS) allows simultaneous communication to a plurality of devices regardless of device type and operating system. Accordingly, the MATS performs mobile testing without “jail-breaking” or removing various components of the user device. In one embodiment of the present disclosure, the MATS enables users to securely test mobile applications by supporting data routing behind a security firewall utilizing a transition of communications protocols. Further, various protocols provide a data tunnel allowing multiple concurrent testing sessions for multiple users via an authentication scheme. Additionally, concurrent testing sessions may include single app testing on multiple devices or a plurality of apps testing on a plurality of devices.

Abstract: Aspects of the present disclosure generally relate to systems and methods for facilitating optimization of mobile application testing. In one embodiment, a mobile application testing system (MATS) allows simultaneous communication to a plurality of devices regardless of device type and operating system. Accordingly, the MATS performs mobile testing without “jail-breaking” or removing various components of the user device. In one embodiment of the present disclosure, the MATS enables users to securely test mobile applications by supporting data routing behind a security firewall utilizing a transition of communications protocols. Further, various protocols provide a data tunnel allowing multiple concurrent testing sessions for multiple users via an authentication scheme. Additionally, concurrent testing sessions may include single app testing on multiple devices or a plurality of apps testing on a plurality of devices.

Abstract: Aspects of the present disclosure generally relate to systems and methods for facilitating optimization of mobile application testing. In one embodiment, a mobile application testing system (MATS) allows simultaneous communication to a plurality of devices regardless of device type and operating system. Accordingly, the MATS performs mobile testing without “jail-breaking” or removing various components of the user device. In one embodiment of the present disclosure, the MATS enables users to securely test mobile applications by supporting data routing behind a security firewall utilizing a transition of communications protocols. Further, various protocols provide a data tunnel allowing multiple concurrent testing sessions for multiple users via an authentication scheme. Additionally, concurrent testing sessions may include single app testing on multiple devices or a plurality of apps testing on a plurality of devices.

Abstract: An extended tow dolly frame (24), a cargo platform frame (32), and cargo platform springs (30), assembled together to provide added cushioned cargo carrying space for various types of cargo (14).

Abstract: A stand-off wire management bracket and system having a back panel, side walls extending from the back panel and attachment brackets pivotally connected to the side walls for pivotal attachment of one or more wire panels. The wire panel is connected across the attachment brackets which rotate about a common axis substantially parallel to the back panel, providing access to the rear portion of the wire panel without requiring disconnection of all connecting points, and without requiring excess clearance, or excess slack in cables. The side panels also include stops to limit the rotation of the attachment brackets and any wire panel attached thereto.

Abstract: A hinged wire management panel assembly with two panels hingedly connected by a plurality of hooks integrally-formed in one panel (a wire management panel) which engage slots formed in a second panel (a patch panel.) The hooks have free ends with straight portions which engage the slots when the two panels are mounted to a common rack thereby forming the hinge connection. The hooks also have curved portions which allow the patch panel to slide along the hooks and simultaneously rotate outward when the patch panel is disconnected from the rack. The wire management panel includes wire management brackets which limit the rotation of the patch panel when the patch panel is horizontal.

Abstract: An adjustable fiber storage plate for optical or composite fibers has a commodious open plate design that comprises a base divided into two sections releasably held together; a cylindrical ring extending radially outward from the base, with half the ring extending from one section and half from the other, wherein, when the sections are together, the ring forms a circle having a radius at least equal to the minimum bend radius for an optical fiber; and at least one fiber fastening means in each section, attached to the ring and to the base plate so that a fiber can be held in position around the ring and adjacent to the base. The sections can be mounted together so that the fiber is stored in a circular configuration, or apart, such that the fiber is stored in an oval configuration. Placement of the sections at different distances varies the storage capacity of the plate.