Synonyms for wirelesshart or Related words with wirelesshart

canopen              bacnet              profinet              devicenet              ethercat              winet              lonworks              controlnet              insteon              wirelesshd              senceive              foxcomm              powerlink              rapidio              echonet              profibus              interbus              zwave              lontalk              modbus              lowpan              worldfip              miwi              spacewire              homeplug              sercosiii              wimedia              digimesh              yorktalk              sigtran              ntcip              sntl              wigig              flexray              wusb              hdbaset              unipro              rmcp              lltd              ipxodi              iwarp              wihd              bpdus              hyperlan              irsimple              capwap              fieldbus              hpna              nwk              mstp             



Examples of "wirelesshart"
WirelessHART is a wireless sensor networking technology based on the Highway Addressable Remote Transducer Protocol (HART). Developed as a multi-vendor, interoperable wireless standard, WirelessHART was defined for the requirements of process field device networks.
OCARI distinguishes from protocols such as ZigBee, WirelessHART and Isa100.11a by the following characteristics:
AMS Device Manager supports digital instrument inputs and outputs; FOUNDATION fieldbus, HART, PROFIBUS DP, PROFIBUS PA, and WirelessHART.
WirelessHART was approved by a vote of the 210 member general HCF membership, ratified by the HCF Board of Directors, and introduced to the market in September 2007. On September 27, 2007, the Fieldbus Foundation, Profibus Nutzerorganisation, and HCF announced a wireless cooperation team to develop a specification for a common interface to a wireless gateway, further protecting users' investments in technology and work practices for leveraging these industry-pervasive networks. Following its completed work on the WirelessHART standard in September 2007, the HCF offered ISA an unrestricted, royalty-free copyright license, allowing the ISA100 committee access to the WirelessHART standard.
Dust Networks' underlying time synchronized mesh networking technology has been standardized by the HART Communications Foundation with the WirelessHART protocol, and the International Society of Automation ISA100 standard.
Dust Networks works with industry and standards groups such as WirelessHART, IETF, ISA, and WINA to help drive the adoption of interoperable wireless sensor networking products.
In April 2010, WirelessHart was approved by the International Electrotechnical Commission (IEC) unanimously, making it first wireless international standard as IEC 62591.
In 2012, Nivis was the only company that supports both the ISA100.11a and WirelessHART standards with a single device; by 2015 the company had several competitors in this field.
During the summer of 2009 NAMUR, an international user association in the chemical and pharmaceutical processing industries, conducted a field test of WirelessHART to verify alignment with the NAMUR requirements for wireless automation in process applications.
Setup and configuration is kept to a bare minimum because of the bottom-up approach utilized in the self-organizing network. There is no notion of a coordinator or network manager entity compared to technologies such as Zigbee or WirelessHART. This reduces the effort spent on setup and maintenance.
In 2011, Nivis launched the WirelessHART development kit. later that year the company was awarded Nivis awarded the FIPS-197 Security Certification for Industrial Wireless Solutions utilizing Advanced Encryption Standard (AES) 128 for encryption. Subsequently Nivis launched a smart objects networking platform, using 6LoWPAN, 802.15.4g and 802.15.4e, at IPSO Alliance press conference in Santa Clara, CA.
Nivis supports the Advanced Encryption Standard adopted by the U.S. government and worldwide, as well as FIPS-197 certification, 802.15.4 security level, ISA100.11a MAC and Transport layer security, WirelessHART MAC and Transport layer security, and follow the IPsec standard for securing end-to-end IP communications.
Backward compatibility with the HART “user layer” allows transparent adaptation of HART compatible control systems and configuration tools to integrate new wireless networks and their devices, as well as continued use of proven configuration and system-integration work practices. It on the estimated 25 million HART field devices installed, and approximately 3 million new wired HART devices shipping each year. In September 2008, Emerson became the first process automation supplier to begin production shipments for its WirelessHART enabled products.
IEEE 802.15.4-2003 (Low Rate WPAN) deals with low data rate but very long battery life (months or even years) and very low complexity. The standard defines both the physical (Layer 1) and data-link (Layer 2) layers of the OSI model. The first edition of the 802.15.4 standard was released in May 2003. Several standardized and proprietary networks (or mesh) layer protocols run over 802.15.4-based networks, including IEEE 802.15.5, ZigBee, 6LoWPAN, WirelessHART, and ISA100.11a.
This table lists production ready-to-use certified modules only, not radio chips. A ready-to-use module is a complete system with a transceiver, and optionally an MCU and antenna on a printed circuit board. While most of the modules in this list are ZigBee, Thread, ISA100.11a, or WirelessHART modules, some don't contain enough flash memory to implement a ZigBee stack and instead run plain 802.15.4 protocol, sometimes with a lighter wireless protocol on top.
IEEE 802.15.4 is a technical standard which defines the operation of low-rate wireless personal area networks (LR-WPANs). It specifies the physical layer and media access control for LR-WPANs, and is maintained by the IEEE 802.15 working group, which defined the standard in 2003. It is the basis for the ZigBee, ISA100.11a, WirelessHART, MiWi, SNAP, and Thread specifications, each of which further extends the standard by developing the upper layers which are not defined in IEEE 802.15.4. Alternatively, it can be used with 6LoWPAN, the technology used to deliver the IPv6 version of the Internet Protocol (IP) over WPANs, to define the upper layers.