A method according to the teachings of the present disclosure may include disposing a sheath around a conductor assembly, with an outer surface of the sheath defining spaced apart crowns and valleys. An outlet of at least one ink jet print head may be positioned adjacent the sheath at an angle of 60 degrees to 120 degrees with respect to a longitudinal axis of the sheath. The method may also include using at least one ink jet print head to print marking indicia on the sheath, the marking indicia indicating at least characteristic of the electrical cable assembly.

The present disclosure discloses a hoisting cable with small diameter, high strength, and high flexibility, including an inner conductive core, an insulating layer, an outer conductive wire layer, a tensile layer, and an outer protective layer. The insulating layer is located at an outer side of the inner conductive core and provides insulation between the inner and outer conductors; the outer conductive wire layer is located at an outer side of the insulating layer; the tensile layer is located at an outer side of the outer conductive wire layer; and the outer protective layer is located at an outer side of the tensile layer. The high tensile strength can ensure the safety of hoisting operations, and the small diameter, small bend radius, and high flexibility can ensure the minimization design and the large rope capacity of a winch.

A system may include a controller, an endpoint device, and a cable coupled between the controller and the endpoint device and comprising a communication wire for bidirectionally communicating signals between the controller and the endpoint device and a circuit formed as a part of the cable and communicatively coupled to the communication wire, the circuit having a microcontroller unit configured to communicate identifying information regarding the cable to the controller via the communication wire and without contention with the signals bidirectionally communicated between the controller and the endpoint device.

A system may include a controller, an endpoint device, and a cable coupled between the controller and the endpoint device and comprising a communication wire for bidirectionally communicating signals between the controller and the endpoint device and a circuit formed as a part of the cable and communicatively coupled to the communication wire, the circuit having a microcontroller unit configured to communicate identifying information regarding the cable to the controller via the communication wire and without contention with the signals bidirectionally communicated between the controller and the endpoint device.

Methods, apparatuses, and computer program products for estimating physical disparity for data locality in software-defined infrastructures are disclosed. For each node in a cluster of nodes connected to a switch, vital product data (VPD) of a cable connecting the node to the switch is obtained, and for each cable, a length of the cable is determined from the VPD. A management application assigns a group identifier to each node in the cluster based on the length of the cable connecting the node to the switch. The management application selects a node in the cluster for storing a data set in dependence upon the group identifier of the node.

Methods, apparatuses, and computer program products for estimating physical disparity for data locality in software-defined infrastructures are disclosed. For each node in a cluster of nodes connected to a switch, vital product data (VPD) of a cable connecting the node to the switch is obtained, and for each cable, a length of the cable is determined from the VPD. A management application assigns a group identifier to each node in the cluster based on the length of the cable connecting the node to the switch. The management application selects a node in the cluster for storing a data set in dependence upon the group identifier of the node.

The present invention provides an identifiable armored cable sheath. In accordance with an aspect of the present invention, there is provided an identifiable armored cable sheath comprising: an armored cable sheath having an outer surface, and a visual indicia applied on the outer surface of the cable sheath in a patterned arrangement, wherein the visual indicia possesses visibility features in low light. Another aspect of the present invention provides a method of making an identifiable armored cable sheath comprising: providing an armored cable sheath, and applying a visually distinctive tape to the outer surface of the sheath in a patterned arrangement.

The present invention provides an identifiable armored cable sheath. In accordance with an aspect of the present invention, there is provided an identifiable armored cable sheath comprising: an armored cable sheath having an outer surface, and a visual indicia applied on the outer surface of the cable sheath in a patterned arrangement, wherein the visual indicia possesses visibility features in low light. Another aspect of the present invention provides a method of making an identifiable armored cable sheath comprising: providing an armored cable sheath, and applying a visually distinctive tape to the outer surface of the sheath in a patterned arrangement.

Provided is an anisotropic conductive film manufacturing method capable of reducing manufacturing costs. Also provided is an anisotropic conductive film capable of suppressing the occurrence of conduction defects. The anisotropic conductive film manufacturing method includes: a holding step of supplying conductive particles having a plurality of particle diameters on a member having a plurality of opening parts, and holding the conductive particles in the opening parts; and a transfer step of transferring the conductive particles held in the opening parts to an adhesive film. In the particle diameter distribution graph (X-axis: particle diameter (μm), Y-axis: number of particles) of the conductive particles held in the opening parts, the shape of the graph is such that the slope is substantially infinite in a range at or above a maximum peak particle diameter.

Provided is an anisotropic conductive film manufacturing method capable of reducing manufacturing costs. Also provided is an anisotropic conductive film capable of suppressing the occurrence of conduction defects. The anisotropic conductive film manufacturing method includes: a holding step of supplying conductive particles having a plurality of particle diameters on a member having a plurality of opening parts, and holding the conductive particles in the opening parts; and a transfer step of transferring the conductive particles held in the opening parts to an adhesive film. In the particle diameter distribution graph (X-axis: particle diameter (μm), Y-axis: number of particles) of the conductive particles held in the opening parts, the shape of the graph is such that the slope is substantially infinite in a range at or above a maximum peak particle diameter.