November 19, 2018
Battery-free smart devices closer to reality
Computer scientists hack RFID tags, giving them the ability to sense their environment.
Researchers at the University of 蓝莓视频 have taken a huge step towards making smart devices that do not use batteries or require charging.听听
Professor Omid Abari, Postdoctoral fellow Ju Wang, and Professor Srinivasan Keshav from 蓝莓视频鈥檚 Cheriton School of Computer Science have found a way to hack radio frequency identification (RFID) tags to create battery-free devices. The ubiquitous squiggly ribbons of metal with a tiny chip found in various objects like library books or on the back of cosmetics are commonly used to track inventory in warehouses and factories, prevent theft of merchandise in stores, in bank cards to make contactless payment possible, and even in pets who are microchipped.听
鈥淚t鈥檚 really easy to do,鈥 said Ju Wang, a post-doctoral fellow at 蓝莓视频鈥檚 Cheriton School of Computer Science. 鈥淔irst, you remove the plastic cover from the RFID tag, then cut out a small section of the tag鈥檚 antenna with scissors, then attach a sensor across the cut bits of the antenna to complete the circuit.鈥澨
These battery-free objects, which feature an IP address for internet connectivity, are known as Internet of Things (IoT) devices. If an IoT device can operate without a battery, it lowers maintenance costs and allows the device to be placed in areas that are off the grid.听听
An RFID听tag is modified by cutting out a small part its antenna (silver ribbon) and placing a small light-sensing phototransistor or temperature-responsive resistor (thermistor) on it.
In their stock form, RFID tags provide only identification and location. It鈥檚 the hack Abari鈥檚 team has done 鈥 cutting the tag鈥檚 antenna and placing a sensing device across it 鈥 that gives the tag the ability to sense its environment.听
To give a tag eyes, the research team hacked an RFID tag with a phototransistor, a tiny sensor that responds to different levels of light.听听
By exposing the phototransistor to light, it changed the characteristics of the RFID鈥檚 antenna, which in turn caused a change in the signal going to the reader. They then developed an algorithm on the reader side that monitors change in the tag鈥檚 signal, which is how it senses light levels.听
Among the simplest of hacks is adding a switch to an RFID tag so it can act as a keypad that responds to touch.听听
鈥淢any classrooms have clickers that students use to answer questions or to indicate a choice,鈥 Wang said. 鈥淭hese clickers need a battery to operate. We created a听batteryless听clicker by cutting the RFID鈥檚 antenna and connecting a push-button switch across the gap. You can use several of these modified RFIDs 鈥 one for option A, another for option B, yet another for option C, and so on.鈥澨
The method is cost-friendly too.听
An RFID听tag is听modified by cutting out a small part its antenna (silver ribbon) and placing a small push-button switch on it. If several modified tags are mounted on a surface, they can act as a wireless keypad.
Light-sensing phototransistors cost 5听to 10 cents apiece, temperature-responsive resistors range from 10 to 50 cents each, and simple push-button switches are just pennies. The cost of hacking an RFID with a sensor or switch is trivial, but its practical implementation has two obstacles to overcome 鈥 accuracy and range, a feat these researchers plan on tackling as they continue to develop their devices.听
听
鈥淲e see this as a good example of a complete software-hardware system for IoT devices,鈥 Abari said. 鈥淲e hacked simple hardware 鈥 our main contribution is showing how simple it is to hack an RFID tag to create an IoT device. It鈥檚 so easy a novice could do it.鈥澨
The research paper by Wang, Abari and Professor Srinivasan Keshav titled,听, appeared in the Proceedings of the 24th Annual International Conference on Mobile Computing and Networking, October 29鈥揘ovember 2, 2018, New Delhi, India, 461鈥 70.
Banner image: Postdoctoral fellow Ju Wang (centre) and Professor Omid Abari demonstrate the wireless keypad clicker they invented by hacking RFID sensors with tiny push-button switches.
