WO2009031981A1 - Système de contrôle de communication - Google Patents

Système de contrôle de communication Download PDF

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Publication number
WO2009031981A1
WO2009031981A1 PCT/SG2008/000335 SG2008000335W WO2009031981A1 WO 2009031981 A1 WO2009031981 A1 WO 2009031981A1 SG 2008000335 W SG2008000335 W SG 2008000335W WO 2009031981 A1 WO2009031981 A1 WO 2009031981A1
Authority
WO
WIPO (PCT)
Prior art keywords
transponder
controller
communication
data
signals
Prior art date
Application number
PCT/SG2008/000335
Other languages
English (en)
Inventor
Yan Wah Michael Chia
Siew Weng Leong
Kim Loon Chee
Original Assignee
Agency For Science, Technology & Research
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Agency For Science, Technology & Research filed Critical Agency For Science, Technology & Research
Publication of WO2009031981A1 publication Critical patent/WO2009031981A1/fr

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Classifications

    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06KGRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
    • G06K7/00Methods or arrangements for sensing record carriers, e.g. for reading patterns
    • G06K7/0008General problems related to the reading of electronic memory record carriers, independent of its reading method, e.g. power transfer
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01DMEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
    • G01D21/00Measuring or testing not otherwise provided for
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W88/00Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
    • H04W88/02Terminal devices

Definitions

  • the present invention generally relates to wireless network communication. More particularly, the invention relates to facilitating and controlling communication with peripheral devices within a wireless communication.
  • RF transceivers in transponders have complex designs.
  • Conventional implementations for wireless communication employ devices such as battery assisted passive (BAP) transponders or standard commercial 'single solution package' chips.
  • BAP battery assisted passive
  • the devices deployed in conventional methods are complex.
  • BAP transponders require supply of power. Typically, power is supplied from a battery to a BAP transponder. An interface is also required for inter-coupling the BAP transponders and peripheral devices.
  • FIG. 1 An example of a typical commercial 'single solution package' chip 100 comprising a RF transceiver 110 is shown in Fig. 1.
  • a typical commercial 'single solution package' chip 100 comprising a RF transceiver 110 is shown in Fig. 1.
  • Such 'single solution package' chips comprise many complex components and are devices with high power requirements, contributing to their complexity and high power consumption respectively.
  • functional blocks such as a low noise amplifier, mixer, a frequency synthesizer, an analog to digital converter (ADC), a digital to analog converter (DAC) and a power amplifier making up the RF transceiver contribute to the complexity thereof and consequently to that of the 'single solution package' chips.
  • ADC analog to digital converter
  • DAC digital to analog converter
  • an apparatus for controlling and facilitating communication with peripheral devices within a wireless communication network comprises a transponder for at least one of transmitting and receiving communication signals via an antenna.
  • the apparatus also comprises a controller for controlling communication of data between the transponder and at least one peripheral device.
  • the peripheral device communicates with the transponder via the controller.
  • the data communicated via the controller is communicated as data signals between the transponder and the controller.
  • the transponder further, interfaces between the communication signals and the data signal.
  • An isolation circuit is configured with the transponder and the controller for substantially impeding RF communication between the transponder and the controller to substantially reduce attenuation in strength of the data signals being communicated between the transponder and the controller.
  • a communication control system for controlling and facilitating communication with peripheral devices within a wireless communication network.
  • the communication control system comprises an antenna and a transponder.
  • the controller at least one of transmits and receives communication signals via the antenna.
  • the communication control system also comprises at least one peripheral device and a controller for controlling communication of data between the transponder and the peripheral device.
  • the peripheral device communicates with the transponder via the controller.
  • the data communicated via the controller is communicated as data signals between the transponder and the controller.
  • the transponder further, interfaces between the communication signals and the data signal.
  • An isolator is configured with the transponder and the controller for substantially impeding RF communication between the transponder and the controller to substantially reduce attenuation in strength of the data signals being communicated between the transponder and the controller.
  • a communication control method for controlling and facilitating communication with peripheral devices within a wireless communication network.
  • the communication control method preferably comprises a first control scheme and a second control scheme.
  • the communication control method comprises extracting data from communication signals received by a transponder.
  • the communication signals are received by the transponder via an antenna from a wireless network.
  • the data are communicated as data signals to a controller.
  • the data signals are communicated via an isolator.
  • the controller operates at least one peripheral device based on the data communicated by the transponder.
  • the isolator is configured with the transponder and the controller for substantially impeding RF communication between the transponder and the controller to substantially reduce attenuation in strength of the data signals being communicated between the transponder and the controller.
  • the communication control method comprises operating at least one peripheral device by a controller.
  • the controller obtains data from the peripheral device.
  • the data is communicated to a transponder as data signals.
  • the data signals are communicated via an isolator.
  • the data is inserted into communication signals transmitted by the transponder.
  • the communication signals are transmitted via an antenna through a wireless network.
  • the isolator is configured with the transponder and the controller for substantially impeding RF communication between the transponder and the controller to substantially reduce attenuation in strength of the data signals being communicated between the transponder and the controller.
  • FIG. 1 shows a component layout of a conventional wireless communication implementation using a 'single solution package' chip
  • FIG. 2a-b shows a communication apparatus, in accordance with one aspect of the invention, for facilitating communication of peripheral devices within a wireless communication
  • FIG. 3 shows the relationship between a controller transmission and a feedback signal
  • FIG. 4 shows a communication control system in accordance with another aspect of the invention, for controlling and facilitating communication with peripheral devices within a wireless communication;
  • FIG. 5a-b shows a first communication control scheme and a second communication control scheme of a communication control method, in accordance with yet another aspect of the invention, for controlling and facilitating communication with peripheral devices within a wireless communication.
  • the apparatus 200 comprises a controller 210, powered by a power supply 220, an isolator 230 and a transponder 240.
  • the controller 210 is preferably a microcontroller for controlling communication of data between the transponder 240 and a peripheral device 250.
  • the data communicated via the controller 210 and the peripheral device 250 is communicated as data signals between the controller 210 and the transponder 240.
  • the power supply 220 is preferably a battery.
  • the transponder 240 is preferably a passive transponder for at least one of transmitting and receiving communication signals via an antenna 260.
  • the transponder 240 for converting between at least one of transmitted and received communication signals and the data signal.
  • the transponder 240 communicates with the antenna 260 and at least one of transmits and receives the communication signals, preferably, as RF signals.
  • the communication signals are preferably transmitted via backscattering.
  • the transponder 240 is a passive transponder configured as a power assisted transponder. The passive transponder when configured as a power assisted transponder, allows for a longer communication distance when communication signals are at least one of transmitted and received via the antenna 260.
  • An example of configuring the passive transponder as a power assisted transponder is to supply power to the passive transponder from the power supply 220 through the controller 210.
  • the controller 210 is preferably configured to supply power to the passive transponder when communication activities from the passive transponder are present.
  • the controller 210 is programmed to supply power to the passive transponder when the controller 210 detects that there are communication activities from the passive transponder. Conversely, when there are no communication activities detected from the passive transponder, the controller 210 does not supply power to the passive transponder. Therefore power consumption can be reduced when the passive transponder is configured as a power assisted transponder to allow for longer communication distance during the communication of signals.
  • Conventional methods, such as periodic software polling between the controller 210 and the transponder 240 are implementable to enable detection of communication activities from the transponder 240.
  • the controller 210 comprises a first input/output (I/O) port 210a and a second I/O port 210b.
  • the transponder 240 comprises a RF port 240a.
  • the controller 210 is coupled to the peripheral device 250 via the first I/O port 210a. Further coupled to the controller 210 is the transponder 240.
  • the controller 210 is coupled to the transponder 240 via the second I/O port 210b and the RF port 240a.
  • the controller 210 is a baseband device that operates at baseband frequencies whilst the transponder 240 is a radio frequency (RF) device.
  • the transponder 240 preferably operates at ultra high frequency (UHF) with a frequency range including 800MHz - 960MHz.
  • UHF ultra high frequency
  • the transponder 240 Since the transponder 240 is coupled with the controller 210, there is RF communication between the controller 210 and the transponder 240. Therefore, due to the RF communication, any data signals being communicated between the controller 210 and the transponder 240, via the second I/O port 210b and the RF port 240a, will result in severe attenuation of strength of the data signals. This renders the communication of data signals between the controller 210 and the transponder 240 ineffective. Hence, when coupling the controller 210 to the transponder 240 there is a need for energy, power and information to be efficiently communicated between the controller 210 and the transponder 240.
  • impedance of the RF port 240a of the transponder 240 is susceptible to impedance changes.
  • the impedance changes of the RF port 240a may cause undesired variations during the RF communication.
  • impedance changes of the RF port 240a of the transponder 240 may cause undesired variations during the RF communication.
  • the isolator 230 is configured with the controller 210 and the transponder 240 for impeding the RF communication between the controller 210 and the transponder 240 so as to substantially reduce the aforementioned severe attenuation. Furthermore, the isolator 230 reduces impedance changes of the RF port 240a of the transponder 240 during RF communication via the antenna 260. Preferably, the isolator 230 substantially prevents any impedance change of the RF port 240a of the transponder 240 during RF communication via the antenna 260.
  • the isolator 230 is configured with the controller 210 and the transponder 240 by one or a combination of wired coupling and wireless coupling.
  • Wired coupling is preferably implementable by disposing RF chokes between the second I/O port 210b of the controller 210 and the RF port 240a of the transponder 240.
  • the RF chokes couples the controller 210 to the passive transponder 240 via the second I/O port 210b and RF port 240a respectively.
  • Wireless coupling can be implemented by various methods known in the art, for example, inductive coupling.
  • the first I/O port 210a of the controller 210 comprises a peripheral pin 212a, as shown in Fig. 2b.
  • the second I/O port 210b of the controller 210 comprises a first antenna pin 214a and a second antenna pin 214b.
  • the controller 210 preferably, further comprises a converter 216 and a comparator 218.
  • the peripheral device 250 is coupled to the converter 216 via the peripheral pin 212a.
  • the converter 216 converts between analogue and digital data formats.
  • the peripheral device 250 is preferably an analogue device sending data, in the analogue format, to the controller 210.
  • the peripheral device 250 is alternatively an analogue device receiving data from the controller 210.
  • the converter 216 receives the data, in the analogue format.
  • the converter 216 converts the data from an analogue format to a digital format so that the data is formatted for use by the controller 210.
  • the converter 216 converts the data to the analogue format before the output signal is received by the peripheral device 250.
  • the RF port 240a of the transponder 240 comprises a first RF pin 242a and a second RF pin 242b.
  • the antenna 260 comprises a first terminal 262 and a second terminal 264.
  • the controller 210 is coupled to the isolator 230 via the first and second antenna pins 214a/214b. Further coupled to the isolator 230 are the transponder 240 and the antenna 260.
  • the antenna 260 and the transponder 240 are coupled to the isolator 230 via, respectively, the first and second terminals 262/264 and the RF port 240a.
  • the isolator 230 comprises a first RF choke 232 and a second RF choke 234.
  • Each of the first and second RF choke 232/234 is preferably a chip inductor.
  • each of the first and second RF choke 232/234 is a meander inductor.
  • the first and second RF choke 232/234 couples the controller 210 to the transponder 240 and the antenna 260.
  • the first RF choke 232 couples the controller 210 to the transponder 240 and the antenna 260 via the first antenna pin 214a of the controller 210, the first RF pin 242a of the transponder 240 and the first terminal 262 of the antenna 260.
  • the second RF choke 234 couples the controller 210 to the transponder 240 and the antenna 260 via the second antenna pin 214b of the controller 210, the second RF pin 242b of the transponder 240 and the second terminal 264 of the antenna 260.
  • Signals are communicated between the controller 210 and the transponder 240 via the first antenna pin 214a and the first RF pin 242a.
  • the comparator 218 of the controller 210 receives a feedback signal from the transponder 240 via the second antenna pin 214b.
  • a resistor 270 is connected to the controller 210 via the second antenna pin 214b.
  • the resistor 270 preferably serves to limit electric current into the comparator 218 of the controller 210.
  • voltage across the resistor 270 is also varied as a function of the feedback from the transponder 240.
  • a controller transmission 345 is transmitted to the transponder 240 from the controller 210 via the first antenna pin 214a and first RF pin 242a.
  • the feedback signal 395 generated by the transponder 240 is transmitted to the controller 210 via second antenna pin 214b and second RF pin 242b.
  • the controller transmission 345 comprises a command signal 345a as shown in Fig. 3.
  • An example of the response characteristics is demonstrated by providing the command signal 345a to the transponder 240.
  • the command signal 345a is first transmitted to the transponder 240 from the controller 210 via the first antenna pin 214a.
  • the feedback signal 395 is then generated by the transponder 240 and transmitted to the controller 210 via the second RF pin 242b.
  • Response of the feedback signal 395 comprises a first state 395a, a second state 395b and a third state 395c.
  • the first state 395a is represented by a flat line which indicates a null feedback signal.
  • the null feedback signal indicates the absence of the command signal 345a.
  • the second state 395b is represented by a ramp line showing the initiation of the feedback signal 395 in response to the command signal 345a being detected.
  • the third state 395c shows the feedback signal 395 responding in relation to the command signal 345a.
  • the feedback signal 395 allows the controller 210 to check the response of the transponder 240 when needed. For example, when the controller 210 acts as a reader for receiving information from the transponder 240, the controller 210 will need to check the feedback signal 395 from the transponder 240 before retrieving information from the transponder 240. Alternatively, when the controller 210 attempts to transmit information to the transponder 240, the feedback signal 395 will also indicate the readiness of the transponder 240 to receive information from the controller 210, particularly, when transmitting information to the transponder 240 employing certain standard protocols such as EPC global class 1 generation 2.
  • the apparatus 200 is deployed in a communication control system 400, as shown in Fig. 4.
  • the communication control system 400 preferably comprises one or more of the apparatus 200 and a reader/interrogator 410 for establishing a wireless network 420.
  • the apparatus 200 is deployed in the communication control system 400 with the peripheral device 250 being a sensor or an actuator.
  • the sensor When deployed with the peripheral device 250 as a sensor, the sensor transmits data which is in an analogue format, to the controller 210.
  • the controller 210 first converts the data format from analogue to digital format before further processing.
  • the controller 210 after processing the data, produces a data signal.
  • the data signal is transmitted from the controller 210 through the wireless network 420 via the antenna 260.
  • the antenna 260 is coupled to the isolator 230 and the transponder 240.
  • the reader/interrogator 410 receives the transmitted data signal.
  • the controller 210 comprises a protocol firmware that is similar to a protocol firmware used by the reader/interrogator 410 to communicate with the transponder 240.
  • the transponder 240 is preferably a passive transponder operating on Amplitude Shift Keying modulation.
  • the actuator when deployed with the peripheral device 250 as an actuator, the actuator receives a data from the controller 210.
  • the controller 210 receives a data signal from the wireless network 420 via the antenna 260, from the reader/interrogator 410.
  • the antenna 260 is coupled to the isolator 230 and transponder 240.
  • the data signal is processed by the controller 210, upon receipt of the data signal by the controller 210. Appropriate conversion of the data format to analogue format is performed in the controller 210 before receipt by the actuator.
  • the controller 210 provides added intelligence and memory for the transponder to operate within the wireless network 420.
  • the controller 210 enables the communication control system 400 to be adaptable to, for example, changes or increased complexity in communication requirements.
  • the controller 210 further enables the communication control system 400 to be adaptable to user requirements.
  • the apparatus 200 employs a communication control method.
  • the communication control method preferably comprises a first control scheme 500a and a second control scheme 500b as shown in Fig. 5a and Fig. 5b respectively.
  • the communication control method under the first communication control scheme 500a comprises extracting data from communication signals received by the transponder 240 in step 510a.
  • Communication signals provided by, for example, the reader/interrogator 410 are received, from the wireless network 420, by the transponder 240 via the antenna 260.
  • step 520a the data are communicated as data signals to the controller 210.
  • the data signals are communicated via the isolator 230.
  • the controller 210 operates the peripheral device 250 based on the data communicated by the transponder 240 to the controller 210.
  • the isolator 230 is configured with the transponder 240 and the controller 210 for substantially impeding RF communication between the transponder 240 and the controller 210 to substantially reduce attenuation in strength of the data signals being communicated between the transponder 240 and the controller 210.
  • the communication control method under the second communication control scheme 500b comprises operating the peripheral device 250 by the controller 210 for obtaining data in step 510b.
  • the data obtained by the controller 210 is obtained from the peripheral device 250.
  • the data is communicated from the controller 210, via the isolator 230, to the transponder 240 as data signals.
  • the data is inserted into communication signals transmitted by the transponder 240.
  • the communication signals are transmitted through the wireless network 420 via the antenna 260.
  • the isolator 230 is configured with the transponder 240 and the controller 210 for substantially impeding RF communication between the transponder 240 and the controller 210 to substantially reduce attenuation in strength of the data signals being communicated between the transponder 240 and the controller 210.

Abstract

La présente invention concerne un appareil, un procédé et un système permettant de faciliter la communication entre plusieurs périphériques dans un réseau de communication sans fil. L'appareil comprend un transpondeur passif destiné à assurer au moins une fonction parmi l'émission et la réception de signaux de communication par l'intermédiaire d'une antenne. L'appareil comprend également un contrôleur adapté pour contrôler la communication de données entre le transpondeur et au moins un dispositif périphérique. En outre, le transpondeur établit une interface entre les signaux de communication et le signal de données. Un circuit d'isolation est associé au transpondeur et au contrôleur afin d'empêcher sensiblement toute communication RF entre le transpondeur et le contrôleur de façon à réduire ainsi sensiblement l'atténuation de la puissance des signaux de données échangés entre le transpondeur et le contrôleur.
PCT/SG2008/000335 2007-09-07 2008-09-08 Système de contrôle de communication WO2009031981A1 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US93593907P 2007-09-07 2007-09-07
US60/935,939 2007-09-07

Publications (1)

Publication Number Publication Date
WO2009031981A1 true WO2009031981A1 (fr) 2009-03-12

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Application Number Title Priority Date Filing Date
PCT/SG2008/000335 WO2009031981A1 (fr) 2007-09-07 2008-09-08 Système de contrôle de communication

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WO (1) WO2009031981A1 (fr)

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6838989B1 (en) * 1999-12-22 2005-01-04 Intermec Ip Corp. RFID transponder having active backscatter amplifier for re-transmitting a received signal
US6853294B1 (en) * 2000-07-26 2005-02-08 Intermec Ip Corp. Networking applications for automated data collection
WO2006003648A2 (fr) * 2004-07-01 2006-01-12 Powerid Ltd. Transpondeur rfid a retrodiffusion alimente par batterie

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6838989B1 (en) * 1999-12-22 2005-01-04 Intermec Ip Corp. RFID transponder having active backscatter amplifier for re-transmitting a received signal
US6853294B1 (en) * 2000-07-26 2005-02-08 Intermec Ip Corp. Networking applications for automated data collection
WO2006003648A2 (fr) * 2004-07-01 2006-01-12 Powerid Ltd. Transpondeur rfid a retrodiffusion alimente par batterie

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