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{{Infobox OS
{{db-nocontent}}
| name = WISP
| logo =
| screenshot =
| caption =
| developer = [[Intel Research]] Seattle
| family = [[Embedded operating system]]s
| released =
| language =
| ui =
| license = [[Creative Commons Attribution License]]
| website = https://sites.google.com/uw.edu/wisp-wiki/home
| source_model = [[Open-source software|Open source]]
| kernel_type =
| supported_platforms =
| latest_release_version = 5.1
| latest_release_date =
| latest_test_version =
| latest_test_date =
| marketing_target = [[Wireless sensor network]]s
| programmed_in = [[C (programming language)|C]], [[Assembly language|Assembly]]
| prog_language =
| updatemodel =
| package_manager =
| working_state = Current
}}


A '''wireless identification and sensing platform''' (WISP) is an RFID ([[radio-frequency identification]]) device that supports sensing and computing: a microcontroller powered by radio-frequency energy.<ref>
{{hangon}}
{{cite book
| title = RFID and sensor networks: architectures, protocols, security, and integrations
|author1=A. Mitrokatsa |author2=C. Dougligeris
|name-list-style=amp |editor1=Y. Zhang |editor2=L. Tianruo Yang |editor3=J. Chen | chapter = Integrated RFID and sensor networks: architectures and applications
| publisher = CRC Press
| year = 2009
| isbn = 978-1-4200-7777-3
| page = 517
| chapter-url = https://books.google.com/books?id=SIJLavpUAJoC&pg=PA517
}}</ref>
That is, like a passive RFID tag, WISP is powered and read by a standard off-the-shelf RFID reader, harvesting the power it uses from the reader's emitted [[radio]] [[Signal (electronics)|signals]]. To an RFID reader, a WISP is just a normal EPC gen1 or gen2 tag; but inside the WISP, the harvested energy is operating a 16-bit general purpose microcontroller. The microcontroller can perform a variety of computing tasks, including sampling sensors, and reporting that sensor data back to the RFID reader. WISPs have been built with light sensors, temperature sensors, and strain gauges. Some contain accelerometers.<ref>
{{cite book
| title = Ambient intelligence: European conference, AmI 2007, Darmstadt, Germany, November 7-10, 2007 : proceedings
|author1=E. M. Tapia |author2=S. S. Intille |author3=K. Larson |name-list-style=amp |editor1=B. Schiele |editor2=A. K. Dey |editor3=H. Gellersen | chapter = Portable wireless sensors for object usage sensing in the home: challenges and practicalities
| publisher = Springer
| year = 2007
| isbn = 978-3-540-76651-3
| page = 23
| chapter-url = https://books.google.com/books?id=TGo1Ikv9ECoC&pg=PA23
}}</ref>
WISPs can write to flash and perform cryptographic computations. The WISP was originally developed by [[Intel Research]] [[Seattle]], but after their closure development work has continued at the Sensor Systems Laboratory at the University of Washington in Seattle.

== Implementation ==

The WISP consists of a board with power harvesting circuitry, demodulator, modulator, microcontroller, external sensors, and other components such as EEPROM and LED.

== Applications ==

WISPs have been used for light level measurement, acceleration sensing, [[cold chain]] monitoring (passive data logging), and [[cryptography]] and [[security]] applications.

== See also ==
* [[Indian Institute of Remote Sensing]]
* [[Intel Research Lablets]]
* [[Mobile phone based sensing software|Remote sensing in mobile telecommunications]]
* [[NODE (wireless sensor)|NODE platform]]
* [[Quality control system for paper, board and tissue machines|Quality control system (QCS) for web and papers]]
* [[SWARM]]
* [[List of wireless sensor nodes|Wireless sensor network nodes]]


== References ==
== References ==

[WISP - Intel Research Seattle] - http://www.seattle.intel-research.net/wisp/
<references/>

==External links==
* {{cite web|url= https://sites.google.com/uw.edu/wisp-wiki/home|title= WISP wiki page}}
* {{cite web|url= https://sensor.cs.washington.edu/WISP.html|title= Sensor Systems Lab WISP description}}
* {{cite journal|title= Design of an RFID-based battery-free programmable sensing platform |date= 2018-06-06|author1= Alanson P. Sample | author2 = Daniel J Yeager | author3 = Pauline S Powledge | author4 = Alexander V Mamishev | author5 = Joshua R Smith | journal = IEEE Transactions on Instrumentation and Measurement | volume = 57 | issue = 11 | pages = 2608–2615}}

* {{cite journal|title= Multi‐Parametric Sensing Platforms Based on Nanoparticles|date= Dec 13, 2016|author1= M. Segev-Bar|author2= N. Bachar|author3= Y.Wolf|author4= B. Ukrainsky|author5= L. Sarraf|author6= H. Haick|journal= Advanced Materials Technologies|volume= 2 | issue= 1|pages = 1600206|quote= [...] potentially to differentiate between the different signals. They have advantages in fields that include wearable systems, humanoid robotics, structural health monitoring and precision agriculture, [...]|doi = 10.1002/admt.201600206|s2cid= 63385571}}

[[Category:Wireless sensor network]]
[[Category:Ubiquitous computing]]
[[Category:Automatic identification and data capture]]
[[Category:Radio-frequency identification]]

Latest revision as of 22:00, 28 March 2023

WISP
DeveloperIntel Research Seattle
Written inC, Assembly
OS familyEmbedded operating systems
Working stateCurrent
Source modelOpen source
Latest release5.1
Marketing targetWireless sensor networks
LicenseCreative Commons Attribution License
Official websitehttps://sites.google.com/uw.edu/wisp-wiki/home

A wireless identification and sensing platform (WISP) is an RFID (radio-frequency identification) device that supports sensing and computing: a microcontroller powered by radio-frequency energy.[1] That is, like a passive RFID tag, WISP is powered and read by a standard off-the-shelf RFID reader, harvesting the power it uses from the reader's emitted radio signals. To an RFID reader, a WISP is just a normal EPC gen1 or gen2 tag; but inside the WISP, the harvested energy is operating a 16-bit general purpose microcontroller. The microcontroller can perform a variety of computing tasks, including sampling sensors, and reporting that sensor data back to the RFID reader. WISPs have been built with light sensors, temperature sensors, and strain gauges. Some contain accelerometers.[2] WISPs can write to flash and perform cryptographic computations. The WISP was originally developed by Intel Research Seattle, but after their closure development work has continued at the Sensor Systems Laboratory at the University of Washington in Seattle.

Implementation

[edit]

The WISP consists of a board with power harvesting circuitry, demodulator, modulator, microcontroller, external sensors, and other components such as EEPROM and LED.

Applications

[edit]

WISPs have been used for light level measurement, acceleration sensing, cold chain monitoring (passive data logging), and cryptography and security applications.

See also

[edit]

References

[edit]
  1. ^ A. Mitrokatsa & C. Dougligeris (2009). "Integrated RFID and sensor networks: architectures and applications". In Y. Zhang; L. Tianruo Yang & J. Chen (eds.). RFID and sensor networks: architectures, protocols, security, and integrations. CRC Press. p. 517. ISBN 978-1-4200-7777-3.
  2. ^ E. M. Tapia; S. S. Intille & K. Larson (2007). "Portable wireless sensors for object usage sensing in the home: challenges and practicalities". In B. Schiele; A. K. Dey & H. Gellersen (eds.). Ambient intelligence: European conference, AmI 2007, Darmstadt, Germany, November 7-10, 2007 : proceedings. Springer. p. 23. ISBN 978-3-540-76651-3.
[edit]
  • "WISP wiki page".
  • "Sensor Systems Lab WISP description".
  • Alanson P. Sample; Daniel J Yeager; Pauline S Powledge; Alexander V Mamishev; Joshua R Smith (2018-06-06). "Design of an RFID-based battery-free programmable sensing platform". IEEE Transactions on Instrumentation and Measurement. 57 (11): 2608–2615.
  • M. Segev-Bar; N. Bachar; Y.Wolf; B. Ukrainsky; L. Sarraf; H. Haick (Dec 13, 2016). "Multi‐Parametric Sensing Platforms Based on Nanoparticles". Advanced Materials Technologies. 2 (1): 1600206. doi:10.1002/admt.201600206. S2CID 63385571. [...] potentially to differentiate between the different signals. They have advantages in fields that include wearable systems, humanoid robotics, structural health monitoring and precision agriculture, [...]