Abstract: An electronic device including: a memory configured to store an address code; a communication interface configured to communicate with one or more node apparatuses among a plurality of node apparatuses by serial communication; and a processor configured to: obtain the address code and an address value corresponding to one node apparatus among the one or more node apparatuses, generate an Ethernet frame including a custom field based on the address code and the address value, and transmit the generated Ethernet frame to the one node apparatus through the communication interface, where the custom field includes: an address code area storing the address code and an address value area storing the address value, and the address code configured to set the address value of the one node apparatus.

Abstract: There is provided an electronic apparatus including one or more processor that obtains at least one target node device corresponding to a user command, among the plurality of node devices, and a control command corresponding to the user command, generates an Ethernet frame based on the content and the control command, the Ethernet frame including a data field, and transmits the Ethernet frame to any one of the one or more node devices through the communication interface. The data field includes a content area configured to store information on the content and a plurality of node areas each corresponding to the plurality of node devices, and the control command is stored in a node area corresponding to the at least one target node device among the plurality of node areas.

Abstract: The LLDPE-LDPE blown film blend is a blown film made from a mixture of unimodal hexene-LLDPE (also referred to as h-LLDPE) and LDPE having a blend ratio between 2%-10% of LDPE added to 98%-90% of h-LLDPE. This blend results in a TD (transverse direction) tear resistance increase by 100% for a composition of between 2%-10% of LDPE with LLDPE. Impact failure energy increases by 20% for the composition of 5% LDPE with 95% h-LLDPE. There is improvement in strength in the TD direction for the composition starting at 10% of LDPE with h-LLDPE. The toughness in the MD (machine direction) direction increases for the compositions of approximately 10% LDPE with h-LLDPE. Moreover, film production of a composition starting at approximately 10% of LDPE with LLDPE requires less energy.

Abstract: The linear low density polyethylene nanocomposite fibers are formed from a linear low density polyethylene matrix having carbon nanotubes embedded therein. The addition of the carbon nanotubes enhances the overall toughness of the material, resulting in increases over conventional linear low density polyethylene in the material's tensile strength, elasticity and ductility. The carbon nanotubes constitute between about 0.08% and 1.0% by weight of the linear low density polyethylene nanocomposite fiber. Optimal toughness is found at about 0.3 wt %. The linear low density polyethylene nanocomposite fibers are made by first melting a quantity of linear low density polyethylene, and then blending a quantity of carbon nanotubes into the melted linear low density polyethylene to form a mixture, The mixture is then extruded to form the linear low density polyethylene nanocomposite fibers, which are then spun in a spinneret die to produce the finished linear low density polyethylene nanocomposite fibers.