JP2004180300A - Ultrasonic identification apparatus and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ultrasonic identification (RFID) apparatus equipped with a detector and several identification tags. <P>SOLUTION: The detector transmits a time slot cycle signal and each cycle signal is divided into several slots. The identification tag receives the time slot cycle signal and each tag is provided with a random generator for generating a random number. Each identification tag responds to the detector in the related time slot corresponding to the random number generated by the random generator in each signal time slot cycle. <P>COPYRIGHT: (C)2004,JPO

Description

  The present invention relates generally to the field of Radio Frequency Identification (RFID) devices. The invention more particularly relates to an RFID device for identifying a tag using the same identification code.

  The use of RFID tags or cards to identify humans or objects is well known. Generally, such tags, when excited, generate a magnetic field or possibly an electric field of a first frequency that is modulated with an identification code. The tag may be an active tag, i.e., a tag that itself has a power supply, or an external tag, as is usually the case when read or placed within the detection range of a reader, e.g., at an entry or exit. It can be a passive tag that requires excitation. Generally, passive devices are used for entrance-type devices, where the transmitting antenna for transmitting the excitation frequency signal for the tag is located at the entrance and identifies the tag and therefore the user or object to which the tag is attached. In order to receive the modulated magnetic or electromagnetic field generated by the excited tag, generally adjacent to the antenna.

  Further, RFID tags can include different identification codes used to identify different objects. For example, by using different identification codes on the tags for staff or visitors, the identification device can be read by the reading device to identify the user while the user passes through the entrance.

  As described above, the reader identifies a tag or tags using different identification codes passing through the detection range. However, the reader cannot simultaneously identify many tags using the same identification code in the detection range. For example, products in a warehouse have tags for identification, and different types of products have tags with different identification codes. The store manager can obtain the quantity of the category only by using the reading unit, but cannot obtain the quantity of each product.

  There is now a need for an improved RFID that can identify the number of tags with the same identification number and detect the temporal change in the number of tags within the detection range.

  In accordance with the shortcomings described in the background, the present invention provides an RFID (Radio Frequency Identification) device for identifying tags having the same identification number in order to improve the above problems.

  Therefore, one of the objects of the present invention is to provide an RFID device for identifying tags having the same identification code.

  Another object of the present invention is to immediately detect a change in the number of tags within a detection range.

  According to the above object, the present invention provides an RFID device comprising a detector and some identification tags. The detector transmits between timeslot cycle times, and each timeslot cycle signal is divided into a number of timeslots. The identification tags receive the time slot cycle signal, and each tag has a respective random generator for generating a random number. Each identification tag is responsive to a detector in an associated time slot corresponding to a random number generated by the random generator in each signal time slot cycle.

  The invention further provides a method for use in an RFID device for identifying tags having the same identification code, comprising: transmitting a continuous time slot cycle signal, wherein each time slot cycle comprises several Splitting into slots, and detecting all responses from the tag in the detection range, where the responses are in different time slots, counting all responses from the tag and determining the presence of the tag. Comparing them with a threshold value for confirmation.

  The foregoing features and advantages associated with the present invention will be readily understood when understood in conjunction with the accompanying drawings, as well as by reference to the following detailed description.

  One preferred embodiment of the present invention will be described in detail below. Nevertheless, the present invention may be embodied in a wide range of other forms than such a clear description, and the scope of the present invention may not be limited to that specified in the claims of the present invention. It should be noted that this is not explicitly limited to

  The present invention provides an ultrasonic identification (RFID) device comprising a detector and several identification tags. The detector sends time slot cycle signals, each cycle signal being split into several stots. The identification tags receive the time slot cycle signal, and each tag has a respective random generator for generating a random number. Each identification tag is responsive to a detector in an associated time slot corresponding to a random number generated by the random generator for each signal time slot cycle.

  The invention further provides a method for use in an RFID device for identifying tags having the same identification code, comprising: transmitting a continuous time slot cycle signal, wherein each time slot cycle comprises several Splitting into slots, and detecting all responses from the tag in the detection range, where the responses are in different time slots, counting all responses from the tag and determining the presence of the tag. Comparing them with a threshold value for confirmation.

  FIG. 1 shows a preferred embodiment of the RFID system of the present invention. An electromagnetic signal of about 13.56 MHz is generated by the detector. The detection range or volume is generated within the transmission range of the electromagnetic wave radio signal. During the passage of the tag through the detection range, the tag receives the electromagnetic radio signal to respond and sends a response signal to the detector. The response signal contains the identification code of the tag. The detector identifies different tags according to different identification codes while the detector receives a response from the tag.

  Further, the tag generates a random number and responds with a response signal in a corresponding time slot according to the random number. By doing so, the detector can identify tags having the same identification code according to response signals in different time slots, but there are many tags having the same identification code within the detection range at the same time.

  FIG. 2 shows the communication timing between the detectors and tags A, B, and C in FIG. The time slot cycle 210 is a 13.56 MHz electromagnetic wave or a so-called scanning signal generated by a detector. The time slot cycle 210 is divided into 32 time slots, and the mute signal 214 is used as an interval between these time slots. The time slot cycle 210 is divided into 32 time slots, and the mute signal 214 is used as an interval between these time slots. For the interval between time slot cycles 210 and 220, four consecutive mute signals are used as time slot cycle interval 212. Mute signal 214 is the result of a temporary interruption of the electromagnetic radio signal from the detector.

  A tag in resonance with commutation provides operating power for the tag. However, an external power supply such as a battery can be used as operating power for the tag in other embodiments.

  One feature of the present invention is that the tag comprises a random generator. According to an embodiment of the present invention, the random generator is a response circuit, which continuously generates random numbers by applying an oscillator uncertainty. The range of random numbers cannot exceed the number of timeslots in the timeslot cycle, and the tag starts counting after receiving the timeslot cycle interval 212 to verify the timeslot.

  As shown in FIG. 2, tag A generates a random number "1", so tag A responds to the detector in the first time slot after time slot cycle interval 212. Similarly, tag B generates a random number "3", so tag B responds to the detector in the third time slot after time slot cycle interval 212. The activation time 220 is a time during which the tag is activated, and is substantially equal to a time slot. The rest of the exclusive startup time 220 is a standby time 222. The tag has halted operation, except that it remains in the standby time 222 state until the corresponding time slot appears.

  Tag C is coupled to the central detection range of time slot cycle 210, so tag C cannot count until the next time slot cycle 211 and cannot respond to the detector.

  As described above, the tag can be activated only at the activation time, so the tag simultaneously generates a new random number that assigns a time slot in the next time slot cycle while the tag is responding to the detector. . Thus, the tag generates a different random number in each time slot cycle while the tag remains in the detection range. This is the tag responding to the detector at a different time slot in each time slot cycle.

  However, the range of random numbers is limited to the number of time slots. For example, the timeslot cycle 210 is divided into 32 timeslots in an embodiment of the present invention, so the range of random numbers must be between 1 and 32. While there are many tags in the detection range, tags with the same random number can occur. Such a condition would cause many tags corresponding to the detector in the same time slot, resulting in a collision. Thus, in another embodiment of the invention, the number of timeslots divided depends on the actual need, and collisions can be reduced by dividing the timeslot cycle into many timeslots. it can.

  In addition, while collisions occur, responses from many tags result in confused responses, and the detector cannot categorize responses from tags.

  As shown in FIG. 2, the tag message responding to the detector includes a preamble, header, ID, checksum, and tail. The random number generated by the random generator is included in the ID field. However, the message format is limited only in the above format, but can be adapted to accommodate different applications.

  FIG. 3 shows a flowchart for a detector that detects tags in the detection range. In this embodiment, the detector sends a time slot cycle signal 300, and the time slot cycle has 32 time slots. Tags in the detection range generate random numbers that are assigned to corresponding time slots for the detector. Thus, the detector receives 302 different tag response messages at different timeslots in the timeslot cycle. Generally, no collision occurs because the random numbers of the tags are different. According to the response messages in different time slots, the detector identifies tags with the same identification code.

  In addition, the detector counts the number of response messages of the tag to resolve any unidentified problems resulting from the collision. For example, as shown in FIG. 2, tag A and tag B have identification codes "001" and "002", respectively, and tag C also has the same identification code "002". While the response messages of tag A, tag B and tag C are in different time slots in a time slot cycle, the detector detects the number of tags and records the number. For example, one tag has an identification code “001” and two tags have an identification code “002”. If there is no collision in the next timeslot cycle, the detector will detect tags A, B and C again and add 1 to their count respectively. If the number of tags is greater than a predetermined threshold, the detector will confirm the presence of the tag. For example, in this embodiment, the predetermined threshold is 5. This means that if tag A, tag B and tag C have no collision during five consecutive time slot cycles, the detector will confirm the presence of tag A, tag B and tag C in the detection range. Further, the maximum limit in this embodiment is 10, and if it is greater than 10, the count is not accumulated.

  The detector is progressively reduced in frequency, so that collisions or noise are left unidentified. Similarly, if the number of tags is less than a predetermined threshold, the detector does not confirm the presence of the tag in the detection range. Furthermore, the frequency of successive time slot cycles is very high, so that the detector can check the number of tags in the detection range in a short time.

  However, using only one threshold in the embodiment for confirming the presence of a tag is not the only application method. Also, other counting methods can be applied to confirm the presence of the tag. Moreover, the intended threshold depends on both the response time and the reliability of the detector.

  As shown in FIG. 3, after step 304, according to the number of counted tags, the detector checks 306 the number of tags using different identification codes in the detection range. By doing so, tags with different identification codes and their number changed in the detection range can be detected simultaneously.

  Although particular embodiments have been described in detail with reference to the drawings, it is intended that the invention be limited only by the appended claims and that various modifications be made without departing from them. Will be apparent to those skilled in the art.

It is a figure showing the ultrasonic identification system of the present invention. FIG. 2 is a diagram illustrating communication timing between a detector and a tag in FIG. 1. It is a figure showing the flow figure of the detector which detects a tag.

Explanation of reference numerals

210 Timeslot cycle 211 Timeslot cycle 212 Timeslot cycle interval 214 Mute signal 220 Timeslot cycle 222 Standby time 300 Detector sends timeslot cycle signal 302 Detects response from tags in different timeslots 304 Tag Step 306 of counting the responses from the devices. Step 306 of checking the number of tags having identification codes having different detection ranges according to the counting result.

Claims (15)

A detector for transmitting a time slot cycle signal, wherein each of the time slot signals is divided into a number of time slots; and a plurality of tags for receiving the time slot cycle signal, A plurality of tags responsive to the detector at different time slots of the time slot cycle signal of the plurality of tags;
An ultrasonic identification (RFID) device comprising:   2. The RFID device according to claim 1, wherein each of the plurality of tags includes a random generator for generating a random number, and the detector in an associated time slot corresponding to the random number in the time slot cycle signal. Wherein the range of the random number does not become larger than the number of time slots.   The RFID device according to claim 2, wherein the random generator is a resonance circuit.   3. The RFID device according to claim 2, wherein the random generator generates a new random number in each of the time slot cycle signals.   The RFID device according to claim 1, wherein the time slot cycle signal is a 13.56 MHz electromagnetic wave.   2. The RFID device according to claim 1, wherein a mute signal is used as an interval between the time slots, and four mute signals are used as an interval between the time slot cycles. A detector for transmitting a time slot cycle signal, wherein each of the time slot cycle signals is divided into a number of time slots; and a plurality of tags for receiving the time slot cycle signal, Each of the plurality of tags includes a respective random generator for generating a random number, each of the plurality of tags being responsive to the detector at an associated time slot corresponding to the random number in each of the time slot cycle signals; A plurality of tags, wherein the tags generate different random numbers in different time slot cycles;
An ultrasonic identification (RFID) device comprising:   The RFID device according to claim 7, wherein the range of the random number is not larger than the time slot. 8. The RFID device of claim 7, wherein the steps of detecting the plurality of tags include:
Transmitting a continuous time slot cycle signal, wherein each said time slot cycle is divided into a number of time slots;
Detecting that all responses generate the tag in the detection range, wherein the responses are in different time slots; and counting the number of responses from the tag to confirm the presence of the tag. Comparing with a predetermined threshold value;
An RFID device, comprising:   8. The RFID device according to claim 7, wherein a mute signal is used as an interval between the time slots, and four consecutive mute signals are used as an interval between the time slot cycles. . A method for a detector for identifying tags having the same identification code in an ultrasonic identification (RFID) device, comprising:
Transmitting a continuous timeslot cycle signal, wherein each said timeslot cycle is divided into a number of timeslots;
Detecting that all responses generate a tag in a detection range, wherein the responses are in different time slots; and counting the number of responses from the tag to confirm the presence of the tag. Comparing to a predetermined threshold;
A method characterized by comprising:   The method of claim 11, wherein the tag uses a random generator to detect a time slot of the response.   The method of claim 11, wherein the tag responds to the detector at a different time slot of each time slot cycle.   The method of claim 11, wherein the time slot cycle signal is a 13.56 MHz electromagnetic wave.   The method according to claim 11, wherein a mute signal is used as an interval between the time slots, and four mute signals are used as an interval between the time slot cycles.

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