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    • 专利摘要:
    METHOD OF READING A RADIO FREQUENCY IDENTIFICATION TAG (RFID), AND RADIO FREQUENCY IDENTIFICATION DEVICE (RFID), comprises devices and methods for reading multiple types of RFID tags [Radio Frequency Identification Device] having different frequencies and/or codification. One or more search signals covering a plurality of RFID bands are transmitted; an indication of the presence of an RFID tag on one of the plurality of RFID bands is detected; an inquiry signal is transmitted having a transmit frequency tuned to a frequency at which the presence signal is detected; a tag response signal comprising tag information associated with the RFID tag is received. A digital response signal based on the tag response signal is processed into a digital signal to obtain the tag information.
    公开号:BR112012018593B1
    申请号:R112012018593-4
    申请日:2011-01-27
    公开日:2022-01-25
    发明作者:Mark Raptis;Graham Ross
    申请人:Carefusion 303, Inc;
    IPC主号:
    专利说明:

    APPLICATION FIELD
    [001] The present patent application refers to radio frequency identification (RFID) systems. In more detail, the present invention discusses and presents RFID dead [sic] devices with multiple software-defined modes. STATUS OF THE TECHNIQUE
    [002] Conventional RFID devices work on a single frequency among several possible ones and employ one encoding mechanism among several different ones. For example, systems currently available on the market operate at 125kHz, 13.56kHz, 915kHz and 2.4GHz frequencies. RFID tags that are attached to items to be tracked operate on a single frequency and, in addition, may use unique and incompatible coding mechanisms to transmit data on that frequency.
    [003] Current RFID systems work by coupling the antenna of RFID transceivers or readers to the antenna of one or more “tags” associated with the items that are to be tracked. Conventional RFID readers are designed to work only with tags provided by a particular vendor. Readers are not designed to universally read multiple types of RFID tags. This limitation of current readers may be attributable to hardware-based processing of the response signal and decoding of tag information. Specific radio circuits are used to detect the information reflected from the RFID tag, filter the information, and shape it before it is fed to the processor. Although this technique is quite simple, it does not have the flexibility to deal with tags of different types, for example tags based on different frequencies and/or encoding regimes. SUMMARY
    [004] The applications described here solve the above problems by providing a multi-mode RFID reader device that is capable of handling different types of RFID tags with different target frequencies and/or encoding mechanisms.
    [005] Some applications provide a method of reading RFID tags. The method may comprise transmitting one or more search signals covering a plurality of RFID bands. The method may further comprise detecting an indication of the presence of an RFID tag on one of the plurality of RFID bands. The method may further comprise reading the RFID tag.
    [006] Some applications provide a method of reading RFID tags. The method may comprise transmitting one or more search signals covering a plurality of RFID bands. The method may further comprise detecting an indication of the presence of an RFID tag on one of the plurality of RFID bands. The method may further comprise transmitting an inquiry signal that has a transmit frequency tuned to a frequency at which the presence indication is detected. The method may further comprise receiving a tag response signal from the RFID tag, wherein the tag response signal comprises tag information associated with the RFID tag. The method may further comprise a digital signal of digitally processing a response signal based on the tag response signal to obtain the tag information.
    [007] Certain applications provide an RFID reading device. The device may comprise an antenna. The device may further comprise a processor configured to transmit one or more search signals covering a plurality of RFID bands via the antenna. The processor may further be configured to detect an indication of the presence of an RFID tag on one of the plurality of RFID bands. The processor may further be configured to read the RFID tag based on a tag response signal received from the tag. The tag response signal may include tag information associated with the RFID tag. The device may further comprise an analog-to-digital converter configured to produce a digital response signal based on the tag response signal. The processor may further be configured to process the digital signal from the digital response signal to obtain the tag information.
    [008] It is to be understood that the above summary and the following detailed description are exemplary and explanatory and are intended to provide a better explanation of the applications as claimed. DESCRIPTION OF THE FIGURES
    [009] The accompanying figures, which are included to provide a further understanding of the present patent application and which are incorporated in and constitute a part of this specification, illustrate disclosed applications and, together with the description, serve to explain the principles of the disclosed applications. In the figures: Figure 1 is a block diagram illustrating an exemplary multimode RFID reader device in accordance with certain applications; Figure 2 is a block diagram illustrating another exemplary multimode RFID reader device in accordance with certain applications; Figure 3 is a block diagram illustrating yet another exemplary multimode RFID reader device in accordance with certain applications; Figure 4 is a flowchart illustrating an exemplary process of searching and reading RFID tags in multiple RFID bands in accordance with certain applications; Figure 5 is a flowchart illustrating an exemplary process for generating and transmitting a modulated query signal for an RFID tag in accordance with certain applications; Fig. 6 is a flowchart illustrating an exemplary process for receiving and processing a response signal from an RFID tag in accordance with certain applications; and Figure 7 is a block diagram illustrating a computer system on which certain applications can be performed. DETAILED DESCRIPTION
    [0010] In the following detailed description, several specific details are set forth to provide a thorough understanding of the described and claimed applications. It will be apparent, however, to one of ordinary skill in the art that the applications can be practiced without some of these specific details. In other examples, well-known structures and techniques were not shown in detail to avoid disclosure being unnecessarily hidden.
    [0011] The word “exemplary” is used here to mean “to serve as a case, illustration or example”. Any application or design described herein as “exemplary” should not necessarily be construed as preferred or advantageous over other applications or designs.
    [0012] The applications of the present patent application address and solve the problems of conventional RFID systems that can normally be employed with only a single type of tags. Applications of the present patent application provide a multi-mode RFID reader device that is capable of handling multiple types of RFID tags based on different target frequencies (e.g., 125kHz, 13.56MHz, 915MHz, and 2, 4 GHz) and/or encoding mechanisms (eg ISO 18000). This device employs a processor that performs in software at least some of the functions conventionally performed by dedicated single-frequency hardware components. Such functions may include, but are not limited to: generating and modulating a transmitting signal, and demodulating, filtering an RFID response signal, and decoding tag information. Certain applications of the multimode RFID reader device are configured to demodulate and decode different RFID systems operating within the full bandwidth of their capabilities, handle RFID tags with multiple frequencies, and process the defined coding algorithms. In addition, new frequencies and encoding mechanisms can be added to its capabilities by reprogramming the processor without making any hardware modifications.
    [0013] Figure 1 is a block diagram illustrating an exemplary multimode RFID reader device 100 in accordance with certain applications. Device 100 includes a processor 101, an array of antennas 103, an antenna selection switch 105, a local oscillator 113, a digital-to-analog converter (DAC) 114, a modulator 115, a output amplifier 117, an input amplifier 121, a demodulator 123, and an analog-to-digital converter (ADC [analog-to-digital converter]) 125. In certain applications, modulator 115 and demodulator 123 are a quadrature modulator. and a quadrature demodulator, respectively.
    [0014] A first output of processor 101 is connected to a control input of local oscillator 113, a second output of processor 101 is connected to a digital input of D/A converter 115, and a third output of processor 101 is connected to an antenna selection switch input 105. An output signal from the local oscillator 113 is connected to an input (transmitter) of the first quadrature modulator 115, and an analog output of the D/A converter 114 is connected to a second input (modulation) of modulator 115. An output of modulator 115 is coupled to an input of output amplifier 117, and an output of output amplifier 117 is coupled to a common terminal of antenna selection switch 105. A set of terminals selectable switches of the antenna selection switch 105 is connected to the antenna array 103. The common terminal of the antenna selection switch 105 is also connected to an input of the input amplifier 121. An output of the amplifier input 121 is connected to a first input of quadrature demodulator 123. A second input of demodulator 123 is connected to signal output of demodulator 123. An output of demodulator 123 is connected to an analog input of A/D converter 125. digital output of A/D converter 125 is connected to an input port of processor 101.
    [0015] Processor 101 is configured (eg programmed) to search for and read various types of RFID tags. An exemplary search operation of RFID reader device 100 is now described. Processor 101 transmits a search signal over a plurality of RFID bands. As used herein, "a search signal" may include a set of RFID band search signals spanning multiple RFID bands to be searched. For example, a seek signal may include a first seek signal for a first RFID band, a second seek signal for a second RFID band, and a third seek signal for a third RFID band. As an example, suppose the RFID reader device 100 is designed to read three RFID bands, namely 125 kHz, 13.56 MHz, and 915 MHz. Processor 100 transmits a first scan signal for the 125 kHz band and looks for an indication of the presence of an RFID tag. In the case of a passive RFID (e.g. a tag without its own power source), the tag's presence indication can be in the form of a sudden drop in energy from a reflected search signal due to a short circuit of an antenna on an RFID tag. If a tag presence indication is detected within the 125 kHz bandwidth, the processor 101 attempts to read the RFID tag by transmitting a query or power-up signal with a target frequency (e.g., the frequency in the which the presence of the tag is detected) in the manner described below.
    [0016] A search signal from a particular RFID band may be a relatively bandwidth signal covering the entire bandwidth of the band (e.g. from about 900MHz to about 928MHz for the 915MHz band) transmitted at the same time. Alternatively, a seek signal may include a set of relatively narrow seek signals (e.g., sections) sequentially transmitted to perform full bandwidth scanning. The steps above are repeated for the other bandwidths, for example 13.56 MHz and 914 MHz.
    [0017] It should be noted that, in certain applications, a plurality of antennas are provided, such as the antenna array 103 shown in Figure 1. This is because a transmitter-receiver antenna that can transmit and receive a signal (for (e.g., search or query signal) on one RFID band may be different from a transceiver type antenna that can transmit and receive a signal on another RFID band. For example, an antenna in the 13.57 MHz band might be a loop antenna designed to be primarily responsive to an RF [radio frequency] magnetic field, while an antenna for the 2.4 GHz band might be a dipole antenna. designed to be sensitive to an electric field. Therefore, between searching or reading from one RFID band to another RFID band, it may be necessary to change the transceiver-type antenna, providing, for example, a selection output from the processor 101 to the selection input of the radio switch. antenna 105. In some applications, a single transceiver-type antenna having a fundamental frequency covering one of the plurality of RFID bands and one or more harmonic frequencies covering one or more remaining RFID bands may be used in place of an array of antennas 103 shown in Figure 1 or in conjunction with one or more other antennas.
    [0018] As indicated above, when the processor 101 detects the presence of an RFID tag at a given bandwidth (e.g., 125 kHz), the processor 101 makes attempts to read the RFID tag by transmitting a query signal. or energizing. An exemplary read operation performed by RFID device 100 is now described. Processor 101 generates a signal indicative of a target frequency (e.g., the frequency at which the presence of the tag is detected) to local oscillator 113. Local oscillator 113 is configured to respond to the signal from processor 101 by generating of a transmitting signal oscillating at one of the frequencies associated with the various types of RFID tags that the device 100 is configured to handle. In certain applications, the local oscillator 113 is a phase-locked loop (PLL) synthesizer, which can generate a variety of output frequencies as multiples of a single reference frequency. In such applications, the target frequency indicative signal provided by processor 101 may include data representing a multiplicative factor for the PLL synthesizer. In other applications, the local oscillator 113 may be a voltage controlled oscillator (VCO [voltage controlled oscillator]).
    [0019] Processor 101 also generates a digital modulation signal which is based on a modulation mechanism associated with the selected type of RFID tag. The modulation mechanism may involve a modulation amplitude, a modulation frequency, or a combination of both. The modulation signal is fed to the DAC 114 which converts the digital modulation signal into an analog modulation signal. The analog modulation signal is also referred to as a “low frequency” signal or a “baseband” signal due to the fact that the signal varies at a frequency that is typically lower than the frequency of the transmitting signal.
    [0020] The transmitter signal (oscillating at the target frequency) generated by the local oscillator 113 and the analog modulation signal generated by the DAC 114 are fed to the modulator 115 which mixes the signals into an analog domain via an analog mixer (not shown). ) and generates a modulated "query" or "power up" signal to be transmitted to an RFID tag via antenna 103 after it has been amplified by output amplifier 117. The query signal comprises the transmitter signal modulated by the modulation signal . In some applications, the transmitting signal is amplitude modulated by the modulating signal. In other applications, the transmitting signal is frequency modulated by the modulating signal. Antenna 103 may be a loop antenna (with single or multiple loops) having bandwidth characteristics to cover the frequency range associated with different types of RFID tags with which the multimode RFID tag reader device 100 is designed to handle .
    [0021] The query signal transmitted in this way creates an electromagnetic (EM) field that induces an AC current in an antenna of a passive RFID tag shown in the drawing within the field, such as the RFID tag 131, for example. This AC current is rectified and the resulting DC current charges a capacitor on tag 131. When the voltage signal across the capacitor is sufficient, an active electronic device in the tag circuit (not shown) is triggered. Once triggered, the tag's electronic device shortens the tag antenna into a sequence of short intervals that are encoded to contain certain tag information, usually the tag's unique ID (eg, an identifier string). Tag information may include, in addition to the unique identification, additional non-volatile information, such as quantity, price, or manufacturing data, associated with the item(s) to which tag is attached. When the tag antenna is throttled, an additional load is created on the antenna 103 of the RFID reader device 100 which induces a voltage drop across the antenna 103. This response alters the "reflected" signals or induces a voltage signal at the antenna 103.
    [0022] The above description with respect to the RFID tag applies to passive RFID tags, which do not contain their own power sources and input signals that reflect incoming query signals in the manner described above. Active RFID tags, on the other hand, contain their own power sources and can actively generate response signals. It should be appreciated by those of ordinary skill in the art, in view of the present disclosure that the system and method described herein can be equally applied to reading active RFID tags as well as passive RFID tags, bearing in mind that active RFID tags would receive a query signal transmitted in this manner and actively generating a response signal, rather than merely reflecting the query signal in the manner described above applicable to passive RFID tags. The actively generated response signal would be processed by the RFID device 100 in much the same way as described above.
    [0023] Returning to Figure 1, the voltage signal induced by the response signal is fed to the input of amplifier 121 and then to demodulator 123 along with the transmitter signal oscillating to the target frequency output by local oscillator 113. The output of demodulator 123 is an intermediate frequency (IF [intermediate frequency]) of the response signal. The IF response signal is then fed to the ADC 125 which converts the IF response signal into a digital response signal. Processor 101 receives the digital response signal and performs a digital signal processing operation including digitally filtering the digital response signal and decoding the tag information based on a decoding algorithm associated with the selected type of RFID tag. . Processor 101 can then determine which tag(s) are within the field region of reader device 100 and report this information, as well as any other additional information contained in the response signal, to an application. inventory or end user. Processor 101 can be programmed to switch frequencies by controlling local oscillator 113 (e.g., a PLL synthesizer) and repeat the process for a new RF target frequency to implement a multi-mode RFID reader device.
    [0024] Figure 2 is a block diagram illustrating another exemplary multimode RFID reader device 200, in accordance with certain applications. Device 200 includes a processor 201, an antenna array 203, an antenna selection switch 205, a local oscillator 213, an output amplifier 217, an antenna 203, an input amplifier 221, a demodulator 223, and an analog converter. - digital (ADC) 225.
    [0025] Again, in certain applications, a description of the search operation (e.g., transmitting a series of search signals to detect the presence of RFID tags in different RFID bands) to the RFID device 200 is substantially the same as that of the exemplary search operation for the RFID device 100 of Figure 1 given above and not repeated here. Instead, an exemplary read operation of the RFID reader device 200 is now described with emphasis on what is different from the read operation of the RFID reader device 100.
    [0026] In this application of the device, the processor 201 controls the local oscillator (e.g. a PLL synthesizer) which generates an RF transmitter signal as described above. The RF transmitter signal is fed to the output amplifier 217 which has a control input (eg, an on-off input). The control input is configured to receive a digital modulation signal from the processor 201 to modulate the amplitude of the transmitting signal. In certain applications, the output of amplifier 217 is a modulated digital query signal, a simple example being an on-off keying (OOK) signal. In such digitally modulated query signals, the signal strength is kept high to indicate a binary “1” and low or zero to represent a binary “0”. Alternatively, such digitally modulated query signals can be generated by an amplifier in conjunction with a digitally controlled analog switch. The output of amplifier 217 is connected to antenna 203, which transmits the modulated query signal.
    [0027] At the receiving part, a response signal carrying tag information induces a voltage signal at antenna 203, to which the voltage signal is fed to the input of amplifier 221 and then demodulated by demodulator 223 with the transmitter signal. The demodulated response signal is fed to the ADC 225, which converts the demodulated response signal into digital representations of the response signal or more simply “a digital response signal”. The digital response signal is then fed to processor 201, where the digital response signal is digitally filtered and decoded to obtain the tag information encoded therein. This device application eliminates the need for a D/A converter and modulator. As before, processor 201 can be programmed to switch frequencies by controlling local oscillator 213 (e.g., a PLL synthesizer) and repeat the process for a new RF frequency to implement a multi-mode RFID reader device.
    [0028] Figure 3 is a block diagram illustrating another exemplary multimode RFID reader device 300 in accordance with certain applications. Device 300 includes a processor 301, an antenna array 303, an antenna select switch 305, a digital-to-analog converter (DAC) 314, an amplifier output 317, an antenna 303, an input amplifier 321, and a analog-to-digital converter (ADC) 325.
    [0029] Again, in certain applications, a description of the search operation (e.g., transmitting a series of search signals to detect the presence of RFID tags in different RFID bands) to the RFID device 300 is substantially the same as the exemplary search operation for the RFID device 100 of Figure 1 given above and not repeated here. Instead, an exemplary read operation of the RFID reader device 300 is now described with emphasis on what is different from the read operation of the RFID reader devices 100 and 200.
    [0030] In this application of the device, the processor 301 has sufficient speed and capacity to directly generate the digital representation of a modulated query signal. In this application, the processor 301 programmatically can perform modulation in the digital versus analog domain as in the device applications described above with respect to Figures 1 and 2. Alternatively, the device 300 may also include a memory (not shown) that is in data communication with processor 301 and configured to store multiple sets of digital representations of modulated query signals designed for different types of tags. Processor 301 can then retrieve a particular set of digital representations corresponding to a selected RFID tag type to be read and the digital representations to be fed to DAC 314, either directly from memory or through processor 301. digital representations are converted to a modulated analog polling signal by DAC 314. The polling signal can be either frequency or amplitude modulated depending on the particular modulation mechanism that is employed. The modulated query signal is then amplified, fed to antenna 303 and transmitted.
    [0031] In the receiving part, a voltage signal at the antenna 303 induced by a response signal from an RFID tag is fed to the input of the amplifier 321 and into the ADC 325 and then directly to the processor 301. Processor 301 then digitally demodulates, filters and decodes the signal to obtain the tag information. The transmit frequency of the modulated query signal can be easily changed, as it is directly controlled by the 301 processor. This implementation is reduced in terms of the number of hardware components compared to the implementations of Figures 1 and 2, but requires larger components width. bandwidth and a high-performance processor to handle the additional functions performed in the digital domain. Such a high performance processor may include a digital media processor, model No. TMS320DM6431 manufactured by Texas Instruments and having a processing speed of 2400 MIPS. However, this digital signal processor is only exemplary.
    [0032] It should be appreciated by those of ordinary skill in the art that the exemplary multimode RFID reader devices shown in Figures 1-3 are provided for illustrative purposes only, and should not be taken as limiting. For example, some of the features of the illustrated examples can be mixed and matched. For example, in alternative applications, modulation can be performed in the digital domain, while demodulation can be performed in the analog domain, or vice versa.
    [0033] Figure 4 is a flowchart illustrating an exemplary process of searching and reading operations of the multimode RFID reader device according to certain applications. Process 400 starts at state 410 and proceeds to state 420, in which a search signal from a first RFID band (e.g., 125 kHz) on a set of RFID bands (e.g., 125 kHz, 13.56 MHz, and 915 MHz) which the device is designed to read, is transmitted. In certain applications, transmitting the search signal of a particular RFID band includes transmitting a relatively bandwidth signal having a spectrum that covers substantially the entire bandwidth of the band (e.g., from about 900 MHz to about 928 MHz for the 915 MHz band). In other applications, transmitting the seek signal includes sweeping a frequency (eg, transmitting a series of narrowband signals or "sections") substantially across the entire bandwidth of the band. The choice of bands or portions of one or more bands that are searched, and therefore the choice of search signals, may depend on the types of RFID tags being searched for. For example, if it is known that RFID tags of interest are supported by only a certain spectral portion of a particular RFID band, the search signal can be configured to scan or cover only the spectral portion rather than the entire spectrum. bandwidth.
    [0034] Process 400 proceeds to a decision state 420, in which a query is made, as if a tag presence indication were detected in response to the transmitted polling signal. In the case of a passive RFID tag, the indication may include a drop in the strength of the reflected search signal. In the case of an active RFID tag, the indication may include a “buzz” signal transmitted over the same or a different frequency by the active RFID tag. If the answer to the query in decision state 430 is No (no indication of tag presence detected), the process 400 proceeds to another decision state 470, in which a query is made to see if there is another band to look for in the set. of RFID bands to be read by the RFID reader device. If the response to the decision query of state 430 is Yes (tag presence indication detected), process 400 proceeds to state 440A,B, where an attempt is made to read a possible RFID tag. The read processes are described below with respect to Figures 5 and 6. After the read attempt, the process 400 proceeds to a decision state 450, in which a query is made as to whether the read was successful. If the answer to the query at decision state 450 is Yes (successful reading), process 400 proceeds to a state 460 where a tag output (e.g. RFID tag ID) is provided, e.g. to a display or a database. After providing the output of the tag, process 400 proceeds to a decision state 470. On the other hand, if the response to the query in decision state 450 is No (unsuccessful reading), process 400 proceeds to decision state 470, without providing tag output.
    [0035] If the answer to the query at decision state 470 is yes (another band to search), the process 400 proceeds to a state 480, in which a search signal is transmitted to the next RFID band (e.g., 13 .56 MHz) and proceeds to decision state 430 after polling or listening for a tag presence indication. On the other hand, if the answer to the query at decision state 470 is No (no other bands to search), for example, because all bands in the set have been searched, process 400 returns to state 420, in which a search signal for the first band (eg 125 kHz) is transmitted again and the remaining states described above are repeated.
    [0036] Figure 5 is a flowchart illustrating an exemplary process 440A for generating and transmitting a query signal to read an RFID tag in accordance with certain applications. Process 440A starts at state 510 and proceeds to state 520, in which a transmit signal (e.g., an RF signal) is generated oscillating at a target frequency (e.g., the frequency at which the presence indication of the tag). The generation of the transmit signal can be performed by a local oscillator, which receives a signal indicative of the target frequency (e.g. data representing a multiplicative factor for a PLL synthesizer) from the processor, as described above with respect to Figures 1 and 2.
    [0037] Process 440A proceeds to a state 530, in which a modulation signal is generated. The modulation signal may be an analog modulation signal that is generated by a digital-to-analog converter (DAC) by converting the digital representations of a modulation signal provided by a processor, as described above with respect to Figure 1. Alternatively, the modulating signal may be a digital modulation signal output by a processor, which may be used to digitally modulate a transmitting signal, as described above with respect to Figure 2.
    [0038] Process 440A proceeds to a state 540 in which a modulated query signal is generated. In certain applications, this may be accomplished by an analog modulator, such as the modulator 115 shown in Figure 1, which mixes a transmit signal with an analog modulation signal as described above with respect to Figure 1. In other applications, this may be obtained by an amplifier having an on-off control input or an amplifier in conjunction with a separate digitally controlled analog switch, as described above with respect to Figure 2. In still other applications, a modulated query signal can be generated directly by means of a digital-to-analog conversion of digital representations, as described above with respect to Figure 3. In such applications, the procedures performed in states 520 and 530 may not be necessary. Process 440A proceeds to a state 550, in which the modulated query signal, after an amplification, is transmitted through an antenna, such as a transceiver-like antenna in the antenna array 103 shown in Figure 1, for example. Process 440A ends in state 590.
    [0039] Figure 6 is a flowchart illustrating an exemplary process 440B for receiving and processing a response signal to read an RFID tag in accordance with certain applications. Process 440B starts at state 610 and proceeds to state 620, in which a response signal from an RFID tag is received by an antenna in a multi-mode RFID reader device. The response signal can be a signal reflected from a passive RFID tag or a signal generated by an active RFID tag. Process 440B proceeds to a state 630, in which a voltage signal at the antenna induced by the response signal is amplified. Process 440B then proceeds to a decision state 640, in which a query is made as to whether the response signal should be demodulated in an analog domain, for example, by an applied hardware demodulator, as in Figures 1 and 2; or in a digital domain, for example by a processor, as in Figure 3. This decision state is provided to illustrate two types (analog and digital) of demodulation, and it should be appreciated that such a query is not typically performed in an application. particular of the multimode RFID reader device. This is because such a device is likely to be pre-configured for analog or digital modulation operation.
    [0040] If the query response at decision state 640 is “analog” (analog demodulation applications), process 440B goes to an analog demodulation band and proceeds to a state 651, in which the amplified response signal is demodulated in the analog domain, for example, by an applied analog demodulator, such as demodulators 123, 223 shown in Figures 1 and 2. In the analog demodulation range, process 440B further proceeds to a state 661, in which a digital response signal (e.g., digital representations of the demodulated response signal), e.g. by an analog-to-digital converter (ADC) such as the ADCs 125, 225 shown in Figures 1 and 2.
    [0041] On the other hand, if the query response at decision state 640 is "digital" (digital demodulation applications), process 440B drives a digital demodulation track and proceeds to a state 653, in which a signal response signal is converted to a digital response signal (e.g., digital representations of the response signal) by an ADC, such as the ADC 325 shown in Figure 3. In the digital modulation range, process 440B advances to a state 663 , in which the digital response signal is digitally demodulated by a processor, as described above with respect to Figure 3.
    [0042] For both analog and demodulation applications, process 440B converges to a state 670, in which the digital response signal (which is now demodulated) is subjected to a digital filtering process by a processor. The type of digital filtering applied depends on the type of RFID tag being read, its associated frequency, and the encoding mechanism. Process 440B proceeds to a state 680, in which the processor decodes the demodulated and filtered digital response signal to obtain the tag information encoded therein. Process 440B ends in state 690.
    [0043] It should be appreciated by those of ordinary skill in the art that the exemplary processes shown in Figures 4-6 are provided for illustrative purposes only, and should not be taken as limiting. For example, referring to Figure 5, generation of the modulation signal in state 530 is typically performed at the same time as generation of the transmit signal in state 520. In some applications similar to those illustrated in Figure 3, states 520 and 530 can be eliminated. Referring to Figure 6, digital demodulation at state 663 can be performed after or at the same time as digital filtering at state 670, for example.
    [0044] Figure 7 is a block diagram illustrating an exemplary computer system 700 in which certain applications disclosed herein may be applied. The computer system 700 includes a bus 702 or other communication mechanism for communicating information, and a processor 704 along with the bus 702 for processing the information. Computer system 700 also includes memory 706, such as random access memory ("RAM" or other dynamic storage device, coupled to bus 702 to store information and instructions to be executed by processor 704 Memory 706 may also be used to store temporary variables or other intermediate information during execution of instructions by processor 704. Computer system 700 further includes a data storage device 710, such as a magnetic disk or optical disk coupled to the bus 702 to store information and instructions.
    [0045] Computer system 700 may be coupled, via an I/O module 708, to a display device (not shown), such as a cathode ray tube (“CRT”) or a liquid crystal display (“LCD”) for displaying information to a computer user. An input device, such as, for example, a keyboard or mouse may also be coupled to computer system 700 via I/O module 708 to communicate information and control processor selections 704.
    [0046] In accordance with certain applications, certain aspects of generating a modulated query signal and processing a response signal from an RFID tag are performed by a computer system 700, in response to a processor 704 that performs one or more sequences of one or more instructions contained in memory 706. Processor 704 may be a microprocessor, a microcontroller, and a digital signal processor (DSP) capable of executing the computer's instructions. Such instructions may be read into memory 706 from another machine-readable medium, such as data storage device 710. Execution of sequences of instructions contained in main memory 706 causes processor 704 to perform the process steps described herein. document. One or more processors in a multiprocessing arrangement may also be used to execute sequences of instructions contained in memory 706. In alternative applications, a hardwired circuit may be used in place of or in combination with software instructions to implement various applications. . Thus, applications are not limited to any specific combination of hardware and software circuits.
    [0047] The term "machine-readable medium" as used herein refers to any medium that participates in providing instructions to processor 704 for execution. Such a medium can take many forms, including, but not limited to, non-volatile media, volatile media, and transmission media. Non-volatile media include, for example, optical or magnetic disks, such as data storage device 710. Volatile media include dynamic memory, such as memory 706. Transmission media include coaxial cables, copper wires, and fiber optics, including the wires that make up the 702 bus. The transmission media may also take the form of acoustic waves or light waves, such as the waves generated during radio frequency and infrared data communications. Common forms of machine readable media include, for example, a floppy disk, floppy disk, hard disk, magnetic tape, any other magnetic media, a CD-ROM, DVD, any other optical media, punch cards, paper tape , any other physical medium with hole patterns, a RAM, PROM, EPROM, FLASH EPROM, any other memory chip or cartridge, a transmitter wave, or any other medium from which a computer can read.
    [0048] The foregoing description has been provided to enable anyone of ordinary skill in the art to practice the various applications described herein. While the foregoing applications have been particularly described with reference to the various figures and applications, it is to be understood that these forms are for illustrative purposes only and should not be construed as limiting the scope of the present application.
    [0049] There may be many other ways to implement this patent application. Various functions and elements described herein may be shared differently from those shown without departing from the spirit and scope of the present patent application. Various modifications to these applications will be readily apparent to those of ordinary skill in the art, and the generic principles defined herein may be applied to other applications. Thus, many changes and modifications can be made to the present patent application, by one of ordinary skill in the art, without departing from the spirit and scope of the present patent application.
    [0050] A reference to an element in the singular is not intended to mean "one and only one", except where indicated, but "one or more". The term “some” refers to one or more. Underlined and/or italicized headings and subheadings are used for convenience only, do not limit the present patent application and are not referred to in connection with the interpretation of the description of the present patent application. All structural and functional equivalents to elements of the various applications of the present patent application described throughout this disclosure, which are known or will later become known to those of ordinary skill in the art, are expressly incorporated herein by reference and are intended to to be encompassed by the invention. Furthermore, nothing disclosed herein is intended to be dedicated to the public irrespective of whether such disclosure is explicitly recited in the above description.
    [0051] All elements, parts and steps described herein are preferably included. It is to be understood that any of these elements, parts and steps may be replaced by other elements, parts and steps or suppressed, as will be obvious to those of ordinary skill in the art.
    [0052] In general terms, the present description discloses devices and methods for reading multiple types of RFID tags with different frequencies and/or encoding schemes. One or more search signals covering a plurality of RFID bands are transmitted. An indication of the presence of an RFID tag on one of the plurality of RFID bands is detected. An inquiry signal is transmitted which has a transmit frequency tuned to a frequency at which the presence indication is detected. A tag response signal containing tag information associated with the RFID tag is received. A digital response signal based on the tag response signal is processed into a digital signal to obtain the tag information. CONCEPTS
    [0053] This text discloses at least the following concepts. Concept 1 A method of reading a radio frequency identification (RFID) tag, the method comprising: transmitting a search signal covering a plurality of RFID bands; detecting the presence indication of an RFID tag on one of the plurality of RFID bands; and reading an RFID tag. Concept 2 The method of Concept 1, characterized by the fact that the search signal includes a collection of search signals for the plurality of RFID bands. Concept 3 The method of Concept 2, characterized in that the transmission of the search signal for a particular RFID band comprises scanning a frequency substantially over the entire bandwidth of the RFID band. Concept 4 The method of Concept 2, characterized in that the transmission of the search signal for a particular RFID band comprises the transmission of a single search signal having a spectrum that substantially covers the entire bandwidth of an RFID band in private. Concept 5 The Concept 1 method, characterized by the fact that the presence indication comprises a drop in the strength of the reflected signal. Concept 6 The method of Concept 1, characterized by the fact that the RFID tag reading comprises: the generation of a modulated query signal having a transmitting frequency defined in a target frequency in which the tag presence indication is detected; receiving a tag response signal from an RFID tag, the tag response signal comprising tag information associated with the RFID tag; producing a digital response signal based on the tag response signal; and digital signal processing of the digital response signal to obtain the tag information, characterized in that such digital signal processing comprises at least digital modulation, digital filtering and digital decoding. Concept 7 The method of Concept 6, characterized by the fact that the generation of the modulated query signal comprises the modulation of a transmitting signal that oscillates at a target frequency with a modulation signal varying at a frequency lower than the target frequency. Concept 8 The method of Concept 7, characterized by the fact that the modulation of the transmitting signal is performed in a digital domain. Concept 9 The Concept 7 method, characterized by the fact that the modulation of the transmitting signal is performed in an analog domain. Concept 10 The Concept 6 method further includes demodulating the tag or digital response signal with a transmitting signal oscillating at the target frequency. Concept 11 The Concept 10 method, characterized by the fact that demodulation is performed in a digital domain. Concept 12 The Concept 10 method, characterized by the fact that demodulation is performed in an analog domain. Concept 13 The method of reading multiple types of RFID tags, which method comprises: transmitting one or more search signals covering a plurality of RFID bands; detecting the presence indication of an RFID tag on one of the plurality of RFID bands; transmitting an inquiry signal having a transmit frequency tuned to a frequency at which the presence indication is detected; receiving a tag response signal from an RFID tag, the tag response signal including tag information associated with the RFID tag; and digital signal processing a digital response signal based on the tag response signal to obtain the tag information. Concept 14 A radio frequency identification device (RFID) comprising: an antenna; and a processor configured to: cause the antenna to transmit a search signal covering a plurality of RFID bands; detecting an indication of the presence of an RFID tag on one of the plurality of RFID bands, and reading the RFID tag based on a tag response signal with tag information associated with the RFID tag. Concept 15 The device of Concept 14, further comprising an analog-to-digital converter configured to produce a digital response signal based on the tag response signal; characterized in that: the processor is further configured to further process the digital signal of the digital response signal to obtain the tag information, and the digital signal processing comprises at least digital modulation, digital filtering and digital decoding. Concept 16 The device of Concept 15, characterized in that the processor is further configured to emit a signal indicative of a target frequency associated with a target frequency at which the indication of presence is detected, and a digital modulation signal, whereby the device further comprises: a local oscillator configured to receive the signal indicative of the target frequency, and to generate a transmit signal that oscillates at the target frequency; a digital-to-analog converter configured to receive the digital modulation signal, and to generate an analog modulation signal, with the analog modulation signal varying at a lower frequency than the target frequency, and an analog modulator configured to receive the transmitter signal and the analog modulation signal, and to generate a modulated query signal by mixing the transmitting signal with the analog modulation signal. Concept 17 The device of Concept 16, characterized in that the local oscillator comprises a phase-locked loop (PLL) synthesizer. Concept 18 The device of Concept 16, characterized by the fact that the analog modulation signal is a quadrature encoded signal. Concept 19 The device of Concept 16, characterized by the fact that the analog modulation signal provides a frequency modulation of the transmitting signal. Concept 20 The device of Concept 16, characterized by the fact that the analog modulation signal provides an amplitude modulation of the transmitting signal. Concept 21 The device of Concept 16 further comprising an analog demodulator configured to receive the response signal and to demodulate it with the transmitting signal to generate an intermediate frequency (IF) of the response signal, characterized in that the response signal IF is converted into the digital response signal by the analog-to-digital converter. Concept 22 The device of Concept 15, characterized by the fact that the processor is further configured to emit a signal indicative of a target frequency at which the presence indication is detected, and a digital modulation signal, the device further comprising: a local oscillator configured to receive the signal indicative of the target frequency and to generate a transmitter signal oscillating at the target frequency, and one or more electronic components configured to receive the transmitter signal and the digital modulation signal, and to generate a modulated signal of questioning by modulating the amplitude of the transmitter signal with the digital modulation signal. Concept 23 The device of Concept 22, characterized in that one or more electronic components comprise an output amplifier having an on/off control digital input configured to receive the digital modulation signal. Concept 24 The device of Concept 22, characterized in that one or more electronic components comprise an output amplifier, and an analog switch connected to the output amplifier and with an on/off control digital input configured to receive the modulation signal digital. Concept 25 The device of Concept 22 further comprising an analog demodulator configured to receive the response signal, and to demodulate it with the transmitting signal to generate an intermediate frequency (IF) of the response signal, characterized in that the IF response is converted into the digital response signal by the analog-to-digital converter. Concept 26 The device of Concept 15, characterized in that the processor is further configured to generate a digital query signal, and the device further comprises a digital-to-analog (D/A) converter configured to receive the digital query signal , and for generating a modulated analog polling signal having its transmitter frequency set at a target frequency at which the presence indication is detected. Concept 27 The Concept 26 device further comprises an output amplifier configured to amplify the modulated analog query signal before the signal is transmitted wirelessly. Concept 28 The Concept 26 device also comprises an input amplifier configured to receive the response signal, and to amplify it, characterized by the fact that the amplified response signal is converted into the digital response signal by the analog-to-digital converter. Concept 29 The device of Concept 14, characterized in that the processor is configured to be initially programmed to read a set of various types of RFID tags, and later reprogrammed to read a new type of RFID tag. Concept 30 The Concept 29 device, where the various types of RFID tags include RFID tags based on different encoding schemes. Concept 31 The device of Concept 29, characterized by the fact that the various types of RFID tags include RFID tags with different RFID bands. Concept 32 The Concept 31 device, characterized by the fact that the RFID bands comprise the 125 kHz, 13.56 MHz, 915 MHz and 2.4 GHz bands. Concept 33 The device of Concept 14, characterized in that the tag response signal comprises a signal reflected from a passive RFID tag. Concept 34 The device of Concept 14, characterized in that the tag response signal comprises a signal generated by an active RFID tag. Concept 35 The device of Concept 14, characterized by the fact that the antenna comprises a set of transceiver-type antennas, each of the transceiver-type antennas being configured to transmit and receive a signal from a different RFID band. Concept 36 The device of Concept 14, characterized in that the antenna comprises a single transceiver-like antenna having a fundamental frequency covering one of the plurality of RFID bands and one or more harmonic frequencies covering one or more remaining RFID bands. Figure legend Figure 1 101) Processor 113) Local Oscillator 114) D/A Converter 115) QMod 123) QDemod 125) A/D Converter 131) RFID Tag Figure 2 201) Processor 213) Local Oscillator 223) QDemod 225) Converter A /D Figure 3 301) Processor 314) D/A Converter 325) A/D Converter Figure 4 410) START 420) Transmit a seek signal to a first band in the RFID band set 430) Detect a presence indication 430 450) Read successfully 460) Provide tag output 470) Another band to look for in the set 480) Transmit a seek signal to the next RFID band Attempt to read the RFID tag 440A, B (Figures 5, 6) Figure 5 510) START 520) Generate a transmitting signal (ex.: RF) 530) Generate a signal of modulation 540) Generate a modulated query signal 550) Transmit the modulated query signal 590) END Figure 6 610) START 620) Receive a response signal 630) Amplify the response signal 640) Analog or Digital Demodulation 651) Demodulate the response signal 653) Produce digital representations 661) Produce digital representations 663) Demodulate the response signal 670) Filter 680) Decode ID information 690) END T1) Analog T2) Digital Figure 7 704) Processor 706) Memory 710) Data Storage T3) I/O Module 704.
    权利要求:
    Claims (20)
    [0001]
    1. “RADIO FREQUENCY IDENTIFICATION (RFID) METHOD”, comprising: generating in a processor a digital representation of an interrogation signal comprising a base signal and a transmitting signal, transmitting a broadband signal, covering the entire width band of a radio frequency identification (RFID) band (420); having selection of a target frequency in the RFID band based on a response to the broadband signal of an RFID band (131) (430); wherein the target frequency (550) is selected from at least two RFID bands associated with the first and second target frequencies, wherein the first target frequency is at least twice the second target frequency; and transmitting an interrogation signal with an antenna (103), characterized in that the antenna (103) is selected from one of at least two antennas (103), a first of at least two antennas (103) associated with the RFID band and a second of at least two antennas (103) associated with a different RFID band, the interrogation signal comprising a baseband signal and a transmitter signal having the selected target frequency (550); and reading the data from the RFID device.
    [0002]
    2. "RADIO FREQUENCY IDENTIFICATION METHOD (RFID)", according to claim 1, further comprising selecting an additional target frequency in the RFID band based on an additional response to the broadband signal from a additional RFID tag (131), characterized in that the additional target frequency is different from the target frequency.
    [0003]
    3. "RADIO FREQUENCY IDENTIFICATION METHOD (RFID)", according to claim 2, characterized in that it also has the transmission of an additional interrogation signal with the selected antenna (103), the additional interrogation signal comprising a signal baseband signal and an additional transmitter signal having the additional target frequency selected.
    [0004]
    4. "RADIO FREQUENCY IDENTIFICATION METHOD (RFID)", according to claim 1, characterized by also having the transmission with the second of at least two antennas (103) of an additional broadband signal that covers all different RFID band bandwidth; selecting an additional target frequency in the different RFID band based on an additional response to the additional broadband signal from an additional RFID tag (131); and transmitting an additional interrogation signal with the second of at least two antennas (103), the additional interrogating signal comprising an additional baseband signal and an additional transmitting signal having the selected additional target frequency.
    [0005]
    5. "RADIO FREQUENCY IDENTIFICATION METHOD (RFID)", according to claim 1, characterized in that it also detects a response to the interrogation signal of the RFID tag (131) by measuring a change in voltage in the antenna (103) (630) selected; and reading the RFID tag (131).
    [0006]
    6. "RADIO FREQUENCY IDENTIFICATION METHOD (RFID)", according to claim 5, characterized in that the target frequency is selected from RFID bands that are associated with target frequencies of 125 kHz, 13.56 MHz, 915 MHz and 2.4 GHz.
    [0007]
    7. "RADIO FREQUENCY IDENTIFICATION METHOD (RFID)", according to claim 5, characterized in that reading the RFID tag (131) comprises: receiving a digital signal from the RFID tag (131) with a processor ( 101); demodulating, with the processor (101), the digital signal, using the transmitter signal with the selected target frequency (663); and decoding the demodulated digital signal (680).
    [0008]
    8. "RADIO FREQUENCY IDENTIFICATION METHOD (RFID)", according to claim 7, characterized in that it also has: the generation, with the processor (101) before transmission, of a digital representation of the interrogation signal; converting the digital representation of the interrogation signal to an analog signal in a digital-to-analog converter (DAC) (114) (530); and providing the analog signal to the selected antenna (103) for transmission by the selected antenna (103).
    [0009]
    9. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", comprising, first and second antennas (103) respectively associated with the first and second RFID bands; an antenna select switch (105) switchably coupled to the first and second antennas (103); and a processor (101) operatively coupled to the antenna select switch (105), characterized in that the processor is configured to: operate the first antenna (103) for transmitting a first seek signal, comprising a first broadband signal that covers the first RFID band; operating the second antenna (103) for transmitting a second search signal, comprising a second broadband signal covering the second RFID band; selecting a target frequency in the first RFID band or the second RFID band based on a response to the first and second wideband signals; operating the antenna selection switch (105) to select one of the first and second antennas (103) based on the selected target frequency; and operating one of the first and second antennas (103) selected for transmitting a modulated interrogation signal, comprising a frequency transmitting signal at the target frequency modulated by a baseband signal.
    [0010]
    10. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 9, characterized in that the processor (101) is also configured to select an additional target frequency in the first RFID band or in the second RFID band based on an additional response to the first and second broadband signals.
    [0011]
    11. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 10, characterized in that the processor is also configured to operate the antenna selection switch (105) to select one of the first and second antennas ( 103) based on the selected additional target frequency; and operating one of the first and second antennas (103) selected based on the selected additional target frequency for transmitting an additional interrogation modulated signal, comprising an additional frequency transmitting signal at the additional target frequency modulated by an additional baseband signal. .
    [0012]
    12. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 9, further comprising a memory (706) communicatively coupled to the processor (101), the memory (706) configured to store a plurality of representations digital modulated interrogation signals; and characterized in that the processor (101) is further configured to retrieve one of a plurality of digital representations of modulated interrogation signals and provides the retrieved digital representation of the plurality of digital representations of modulated interrogation signals as the modulated interrogation signal , the transmitter signal comprising frequency at the target frequency modulated by the baseband signal.
    [0013]
    13. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 9, characterized in that the response to the first and second broadband signals comprises a signal reflected from a passive RFID tag (131) or a signal generated by an active RFID tag.
    [0014]
    14. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 9, characterized in that the first and second antennas (103) comprise a set of transceiver antennas (103), each of the transceiver antennas (103) configured to transmit and receive a signal on a different RFID band.
    [0015]
    15. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 9, characterized in that one of the first and second antennas (103) comprises a single transceiver antenna (103), having a fundamental frequency that covers one of the first and second RFID bands and one or more harmonic frequency(s) covering one or more remaining RFID band(s).
    [0016]
    16. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", comprising: at least two antennas (103) respectively associated with at least two RFID bands associated with the first and second target frequencies, wherein the first target frequency is, at least twice the second target frequency; an antenna selection switch (105) selectively coupled to one of at least two antennas (103); and a processor (101) operatively coupled to the antenna selection switch (105), characterized in that the processor is configured to operate one of at least two antennas (103) to transmit a broadband signal covering the entire width. band of one of at least two RFID bands; determining a target frequency in one of at least two RFID bands based on a response to the wideband signal; operating the antenna selection switch (105) to select one of at least two antennas (103) associated with one of at least two RFID bands; and operating one of at least two antennas (103) selected to transmit an interrogation signal, having a baseband signal and a transmitter signal at the determined target frequency.
    [0017]
    17. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 16, characterized in that the processor (101) is also configured to: receive a digital signal in response to the transmitted interrogation signal; demodulating the digital signal using the transmitting signal with the determined target frequency; and decoding the demodulated digital signal for reading an RFID tag (131).
    [0018]
    18. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 16, characterized in that the processor (101) is also configured for: operation of an antenna (103) different from at least two antennas ( 103) for transmitting an additional broadband signal that covers the entire bandwidth of a different band of at least two RFID bands; determining an additional target frequency in the different band of at least two RFID bands based on an additional response to the additional broadband signal; operating the antenna selection switch (105) to select the antenna (103) different from among at least two antennas (103); and operating the different antenna (103) selected from at least two antennas (103) to transmit an additional interrogation signal, comprising an additional baseband signal and an additional transmitter signal, having the additional target frequency determined.
    [0019]
    19. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 16, characterized in that the determined target frequency is selected from target frequencies of 125 kHz, 13.56 MHz, 915 MHz and 2.4 GHz.
    [0020]
    20. "RADIO FREQUENCY IDENTIFICATION DEVICE (RFID)", according to claim 16, characterized in that it also has a memory (706) configured to store a plurality of sets of information respectively associated with a plurality of types of tags (131), each set comprising a respective encoding scheme and an RFID frequency band.
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    JP2013519160A|2013-05-23|
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    BR112012018593A2|2017-07-04|
    MX2012008766A|2012-11-12|
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    EP2531958B1|2016-01-27|
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    WO2011097118A2|2011-08-11|
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    法律状态:
    2019-01-08| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2019-09-17| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2020-07-07| B07A| Application suspended after technical examination (opinion) [chapter 7.1 patent gazette]|
    2020-11-24| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]|
    2021-04-20| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]|
    2021-12-07| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2022-01-25| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 27/01/2011, OBSERVADAS AS CONDICOES LEGAIS. PATENTE CONCEDIDA CONFORME ADI 5.529/DF, QUE DETERMINA A ALTERACAO DO PRAZO DE CONCESSAO. |
    优先权:
    申请号 | 申请日 | 专利标题
    US12/700,645|US9342716B2|2010-02-04|2010-02-04|Software-defined multi-mode RFID read devices|
    US12/700,645|2010-02-04|
    PCT/US2011/022793|WO2011097118A2|2010-02-04|2011-01-27|Radio frequency identification device and method|
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