KR101187305B1 - Parking position reading device for use in apartment - Google Patents

Abstract

A parking location reader is disclosed that is more convenient to use in a multi-family house and that the parking location can be easily checked in the parking lot. Such parking position reader has a key communication unit. The key communication unit transmits a first frequency signal in response to touch detection or vehicle parking detection, and receives a second frequency signal higher than a frequency of the first frequency signal generated from the high frequency key in response to the first frequency signal. The parking position reader also includes an information generation and confirmation unit. The information generation and confirmation unit receives the second frequency signal to generate and transmit parking location data indicating a parking area of the corresponding vehicle, and searches for parking location information on the corresponding vehicle when the parking confirmation mode is entered. Audibly informs. According to the above parking position reader, the parking position data is generated even without the tag operation of the radio frequency identification tag, and the parking convenience can be easily checked at the parking lot at the time of parking confirmation, thereby increasing convenience of use. .

Description

PARKING POSITION READING DEVICE FOR USE IN APARTMENT}

The present invention relates to the management and verification of the parking location of the apartment house, such as apartments, villas, alliance, multi-family, residential complex, officetel, townhouse, etc. It's about the reader.

Typically, a parking position recognition technique is known in which after a user parks a vehicle in a parking lot, a parking position is recognized by applying a radio frequency identification (RFID) tag to the parking position reader. Here, the parking position information indicating the zone information in the parking lot may be displayed on a household device such as a wall pad or a personal portable terminal.

Since the RFID tag should generally be within a few to several tens of centimeters of the parking position reader, it is quite inconvenient for a user carrying a relatively heavy load in both hands to tag the RFID tag.

In addition, when a user wants to know the area of a parked vehicle, it is cumbersome to check it manually through a household device or a personal portable terminal. For example, when a user arrives at the parking lot by looking at the parking area displayed on the household device, It is also possible to forget the displayed parking area information and not remember it.

The problem to be solved by the present invention is to provide a parking position reader that can perform the parking position recognition by touch detection or vehicle parking detection.

Another problem to be solved by the present invention is to provide a parking position reader to directly check the parking position information in the parking lot.

Another problem to be solved by the present invention is to provide a parking position reader that allows the user to visually or auditoryly check the most recently parked parking location information when entering the parking lot.

In order to achieve the above technical problem, a parking position reader according to an aspect of an embodiment of the present invention,

A key communication unit transmitting a first frequency signal in response to touch detection or vehicle parking detection, and receiving a second frequency signal higher than a frequency of the first frequency signal generated from a high frequency key in response to the first frequency signal;

Receives the second frequency signal to generate and transmit parking location data indicating the parking area of the vehicle, and generates information that visually or aurally notifies by searching the parking location information of the vehicle when entering the parking confirmation mode. And a confirmation unit.

In an embodiment of the present invention, the key communication unit,

LF module that wakes up when the touch detection signal is applied through the touch detection sensor or the vehicle parking detection signal is applied through the vehicle parking detection sensor, and transmits the first frequency signal to activate the corresponding LF module of the high frequency key. and;

And a UHF module configured to receive the second frequency signal applied according to the wake-up of the corresponding UHF module of the high frequency key.

In an embodiment of the present invention, the information generation and confirmation unit,

A parking confirmation key for generating a key signal to allow the entry into the parking confirmation mode;

A communication unit configured to perform data communication when transmitting the parking position data to the parking position server or when receiving the parking position information stored from the parking position server in the parking confirmation mode;

The parking position data is generated by combining the identification code information obtained from the second frequency signal and the location information related to the parking area of the vehicle, and applied to the communication unit, and the corresponding key signal of the parking confirmation key is present. A reader controller configured to search for parking location information on the vehicle and generate notification data for visually or audibly informing the vehicle;

The display unit may display a notification data of the reader controller as text.

In an embodiment of the present disclosure, the speaker may further include a speaker for displaying notification data of the reader controller as a sound.

In an embodiment of the present disclosure, a warning lamp for displaying a parking position by light and sound may be further provided in response to the notification data of the reader controller.

According to an embodiment of the present disclosure, if the identification code information is not applied from the high frequency key after the key signal of the parking confirmation key is generated, an input unit may be further configured to receive a user's operation input and perform parking confirmation. Can be.

According to an embodiment of the present disclosure, when generating the parking position data, the generated parking position data may be further provided with a copy key for wirelessly transmitting and storing the high frequency key.

According to an embodiment of the present disclosure, when the radio frequency identification tag is mounted in the radio frequency key, a radio frequency identification tag recognition unit may be further provided to read user identification information stored in the tag.

In order to achieve the above technical problem, the parking position reader according to another aspect of the embodiment of the present invention,

A key communication unit maintaining a standby state to receive a high frequency signal generated from the high frequency key;

Receiving the high-frequency signal to generate and transmit the parking position data indicating the parking area of the vehicle, and when entering the parking confirmation mode to search for the parking position information for the vehicle to generate and confirm the information visually or auditory A part is provided.

In an embodiment of the present invention, the key communication unit,

A UHF module for receiving the high frequency signal transmitted while the corresponding UHF module of the high frequency key wakes up by a user's key manipulation may be provided.

In an embodiment of the present invention, the information generation and confirmation unit,

A parking confirmation key for generating a key signal to allow the entry into the parking confirmation mode;

A communication unit configured to perform data communication when transmitting the parking position data to the parking position server or when receiving the parking position information stored from the parking position server in the parking confirmation mode;

The parking position data is generated by combining the identification code information obtained from the high frequency signal and the location information related to the parking area of the vehicle, and applied to the communication unit, when the key signal of the parking confirmation key is present to the corresponding vehicle. A reader controller for generating notification data for searching for parking location information and visually or audibly informing;

The display unit may display a notification data of the reader controller as text.

In an embodiment of the present disclosure, the speaker may further include a speaker for displaying notification data of the reader controller as a sound.

In an embodiment of the present disclosure, a warning lamp for displaying a parking position by light and sound may be further provided in response to the notification data of the reader controller.

According to an embodiment of the present disclosure, if the identification code information is not applied from the high frequency key after the key signal of the parking confirmation key is generated, an input unit may be further configured to receive a user's operation input and perform parking confirmation. Can be.

According to an embodiment of the present disclosure, when generating the parking position data, the generated parking position data may be further provided with a copy key for wirelessly transmitting and storing the high frequency key.

According to an embodiment of the present disclosure, when the radio frequency identification tag is mounted in the radio frequency key, a radio frequency identification tag recognition unit may be further provided to read user identification information stored in the tag.

In an embodiment of the present disclosure, an emergency bell may be further provided near the display unit to generate a signal for emergency call.

In an embodiment of the present disclosure, the generated parking position data may be further used for matching linkage or lift call of closed circuit television.

In an embodiment of the present invention, the entry into the parking confirmation mode is performed by pressing the parking confirmation key provided in the parking position reader or pressing the setting key of the high frequency key in the parking lot again after the parking of the vehicle, or the common entrance reader and the parking lot. Under the linkage of the parking position reader at the entrance, it can be performed automatically by reading the user identification code information of the high frequency key.

According to the exemplary embodiment of the present invention as described above, the parking position data is generated without the tag operation of the radio frequency identification tag. In the end, users can park the location data by using the human body's touch, vehicle parking detection, or pressing the parking key installed on the high frequency key without having to tag the radio frequency identification tag embedded in the high frequency key to the parking location reader. Is increased.

In addition, since the parking confirmation can be easily pressed by pressing the parking confirmation key provided on the parking position reader or pressing the setting key of the high frequency key after the parking of the vehicle, the convenience of use is increased.

1 is a block diagram of a constitution of a convenient housing system including a parking position reader according to the present invention
FIG. 2 is a view illustrating an installation implementation of the parking position reader of FIG. 1. FIG.
3 is a detailed implementation example of the high frequency key of FIG.
4 is a detailed implementation example of the parking position reader of FIG.
5 is an operation control flowchart according to the first example of the parking position reader of FIG.
6 is an operation control flowchart according to a second example of the parking position reader of FIG.
7 is an exemplary view illustrating the format of parking position data output from the parking position reader of FIG. 1.

Hereinafter, a preferred embodiment of a parking position reader suitable for employment in a multi-family house will be described with reference to the accompanying drawings.

In the following embodiments, many specific details are described by way of example with reference to the drawings, which, however, have been described without any intention other than intention to aid a more thorough understanding of the invention to those skilled in the art. shall. However, it will be understood by those skilled in the art that the present invention may be practiced without these specific details. The detailed configuration and operation of the known home network server, RFID tag, generation device, parking position server, CCTV controller, and elevator controller are not described in detail in order not to obscure the subject matter of the present invention.

1 is a block diagram illustrating a system for providing a convenience of a multi-family house including a parking position reader according to the present invention.

Referring to the drawings, the apartment housing convenience system is a radio frequency (RF) key 10, a plurality of parking location readers (100, 100-1, 100-n), relay unit 150, parking location server 200 , CCTV controller 400, home network server 220, elevator control unit 300, elevator 320, and a plurality of generation devices (250,251,252).

The relay unit 150 is connected to the plurality of parking position readers 100, 100-1, and 100-n through a line L10. The high frequency key 10 may perform wireless communication with the plurality of parking position readers 100, 100-1, and 100-n.

The parking location server 200 is connected to the relay unit 150 through a line L12, and is connected to the CCTV controller 400 through a line L16. The home network server 220 is connected to the parking location server 200 through a line L14, and is connected to the plurality of generation devices 250, 251, and 252 through a line L18. The elevator control unit 300 that controls the elevator 320 is connected to the line L14 through the line L15.

In FIG. 1, although the parking location readers 100, 100-1, 100-n and the generation devices 250, 251, and 252 are each composed of three, the parking location server 200 may have several tens or more. It should be understood that hundreds of parking position readers and household devices can be connected.

In addition, the relay unit 150 may be removed when the plurality of parking position readers 100, 100-1, and 100-n are limited to several teenagers or less.

On the other hand, when the relay unit 150 has a function of performing a wireless relay, short-range wireless communication such as Zigbee or Bluetooth communication is the parking position readers (100, 100-1, 100-n) and the relay unit 150 Can be made in between.

FIG. 2 is a view illustrating an installation implementation of the parking position reader of FIG. 1. The user P1 of the multi-family house carries the high frequency key 10 for generation and confirmation of the parking position information, and the vehicles C1 and C2 in the parking lot are usually parked in the parking area provided in the parking lot. The plurality of parking position readers 100 and 100-1 may be installed corresponding to the pillars CO1 of the parking lot. When the user P1 having the high frequency key 10 parks the vehicle C1 and then touches the parking position reader 100 in the parking area A-3, the parking position reader 100 Generate parking location data. The generated parking position data may be transmitted to the parking position server 200 via the relay unit 150 of FIG. 1. In addition, the parking position reader 100 may generate parking position data even when a detection sensor detecting that the vehicle C1 is parked is connected to the parking position reader 100. Here, the sensor includes at least one of a roof coil, a metal sensor, a load sensor, an ultrasonic sensor, a geomagnetic sensor, an acoustic sensor, a motion sensor, a camera, and a car identification system installed in the parking area or buried in the air. can do. When a parking sensor capable of distinguishing a person from a car can be installed at no cost, connecting the sensor to the parking position reader 100 generates parking position data without the user's touch. . However, it may be more preferable to adopt the touch method in which the user's permissive behavior is implied in terms of burden of installation cost or respect of personal privacy.

When the parking confirmation key is pressed through the key input unit 36 of the high frequency key 10 or the parking confirmation key 130 provided in the parking location reader 100 is pressed, the parking location reader 100 enters the parking confirmation mode. Can be.

Further, after acquiring the identification code information stored in the high frequency key 10 through the common entrance reader provided in the apartment house, the identification code information stored in the high frequency key 10 through the parking position reader installed at the entrance of the parking lot. If again obtained, it may be possible to automatically enter the parking confirmation mode.

That is, entering the parking confirmation mode is performed by pressing the parking confirmation key provided in the parking position reader or pressing the setting key of the high frequency key in the parking lot again after the parking of the vehicle, or by using the common entrance reader and the parking position reader at the entrance of the parking lot. It can be performed automatically by reading the user identification code information of the high frequency key under the linkage of.

Upon entering the parking confirmation mode, the parking location reader 100 searches for parking location information for the corresponding vehicle and visually or visually notifies.

3 is a detailed implementation example of the high frequency key of FIG.

Referring to the drawings, the high frequency key 10 includes an LF module 12, a wake up detection unit 14, a UHF module 20, and a control unit 28. In addition, the high frequency key 10 includes a power supply unit 16, a switch 18, an external I / O 26, a key input unit 36, an encryption unit 32, and an RFID passivator tag unit 34. do.

The UHF module 20 may include a modulator / demodulator 22 and a transmitter / receiver 24, and the controller 28 may include a memory 30.

In FIG. 3, the LF module 12 may be implemented with a universal device "MCP2030" to perform low frequency communications at 125 kHz, and the UHF module 20 may be implemented with a universal device "CC1101" to perform ultra high frequency communications at 447 MHz. It can be implemented as. In this case, the controller 28 may be implemented as a general purpose processor "ATMega88".

The LF module 12 is activated in response to a 125 kHz low frequency signal sent from the LF module 142 in the parking position reader of FIG. That is, the LF module 142 is activated by being supplied with power wirelessly by having an antenna part composed of an inductor and a capacitor. When the LF module 12 is activated, a wake up signal WU is generated and applied to the wake up detector 14. The wake up detecting unit 14 controls the switch SW of the switch 18 to be closed when the wake up signal WU is received. When the switch 18 is controlled in a switched on state (closed), the power of the power supply unit 16 is supplied to the output node OU and applied to the UHF module 20 and the control unit 28.

When the UHF module 20 and the controller 28 are activated, a second frequency signal higher than the frequency of 125 kHz, for example, a frequency signal of 447 MHz, is transmitted from the UHF module 20. The second frequency signal includes unique identification code information of the user of the apartment house. The identification code information may be a unique serial number of the user or data including at least one of a user's name, a call number, a vehicle number, and a telephone number. Here, although the frequency of the second frequency signal is set to, for example, 447 MHz, the present invention is not limited thereto, but may be set to any selected high frequency band, a band of 2.45 GHz, or a band of 5.8 GHz or more.

The external I / O 26 is connected to the controller 28 to perform input and output with the external device. The key input unit 36 may include a parking position generation key and a parking position confirmation key, and generate and apply a user input to the controller 28. In addition, the key input unit 36 may be provided with an emergency key for notifying emergency or emergency situation.

The encryption unit 32 is connected to the control unit 28 to perform a coding function for the security of the identification code information included in the second frequency signal.

The RFID pass tag unit 34 may communicate with a frequency of 13.56 MHz to output unique recognition code information. In this case, the RFID pass tag unit 34 is activated by receiving power wirelessly from the parking position reader when the tag is performed at a close distance of about 30 centimeters or less.

The operation of the contactless RFID tag embedded in the high frequency key 10 is recommended to ISO / IEC 10536 and ISO / IEC14443. In other words, the contact tag is defined as ISO / IEC 7816, but the contactless type is defined as ISO / IEC 10536 for CCIC (Contactless IC Card) and ISO / IEC 14443 for Remote Coupling Communication Card (RCCC). Has been recommended. In order to have a common entrance pass function, parking lot access pass function, traffic and card payment function, or parking location storage function, the high frequency key 10 is USIM which is excellent in security and is used for wireless e-commerce service. It may be implemented in the form of a Universal Subscriber Identity Module (SIM) or a Subscriber Identity Module (SIM). That is, the circuit of the high frequency key 10 may be embedded in a mobile terminal such as a mobile phone in the form of a chip, and the chip may be in the form of a USIM or a SIM. Here, USIM or SIM is a security module (chip set) inserted and used in a mobile terminal. SIM used for GSM mobile communication stores information on a specific user and is used for authentication when connected. Detailed implementation methods of security authentication include HASH LOCK (HL), RANDOM HASH LOCK (RHL), HASH CHAIN (HC), and HASH BASED ID VARIATION. HIDV), CRA (CHALLENGE RESPONSE AUTHENTICATION), etc. may be optionally used.

4 is a detailed implementation example of the parking position reader of FIG. 1. Referring to the drawings,

The parking position reader 100 includes a key communication unit 140 and an information generation and confirmation unit.

The key communication unit 140 transmits a first frequency signal (for example, 125 KHz) in response to touch detection or vehicle parking detection, and generates a higher frequency than the frequency of the first frequency signal generated from the high frequency key in response to the first frequency signal. Receive two frequency signals (e.g., 446 MHz). The key communication unit 140 wakes up when the touch detection signal is applied through the touch detection sensor or the vehicle parking detection signal is applied through the vehicle parking detection sensor to activate the corresponding LF module of the high frequency key. An LF module 142 for transmitting one frequency signal and a UHF module 144 for receiving the second frequency signal applied according to the wake-up of the corresponding UHF module of the high frequency key.

The information generation and confirmation unit receives the second frequency signal to generate and transmit parking location data indicating a parking area of the corresponding vehicle, and visually searches for parking location information on the corresponding vehicle when entering the parking confirmation mode. Or audibly. To this end, the information generation and confirmation unit,

A parking confirmation key 130 for generating a key signal for allowing entry into the parking confirmation mode;

A communication unit 116 for performing data communication when transmitting the parking location data to the parking location server or when receiving the parking location information stored from the parking location server 200 in the parking confirmation mode;

The parking position data is generated by combining the identification code information obtained from the second frequency signal and the location information related to the parking area of the vehicle, and applied to the communication unit, and the corresponding key signal of the parking confirmation key is present. A reader controller 110 for generating notification data for searching for parking location information on a vehicle and visually or acoustically notifying the vehicle;

The display unit 106 may display the notification data of the reader controller as text.

In addition, the parking position reader 100 includes a speaker 129 for displaying the notification data of the reader control unit as a sound, and the warning lamp 121 for displaying the parking position as light and sound in response to the notification data of the reader control unit. It may be provided.

The parking position reader 100 may include an input unit configured to receive a user's operation input and perform parking confirmation when the recognition code information is not applied from the high frequency key 10 after the key signal of the parking confirmation key is generated ( 134).

The parking position reader 100 may further include a copy key 132 for allowing the generated parking position data to be wirelessly transmitted to the high frequency key and stored when the parking position data is generated.

The parking position reader 100 may further include a radio frequency identification tag recognition unit 104 for reading user identification information stored in the radio frequency identification tag 34 when the radio frequency identification tag 34 is mounted in the high frequency key 10. Can be.

In FIG. 4, for example, the LF module 142 may be implemented with a universal device “ATA5276”, and the UHF module 144 may be implemented with a universal device “CC1101”. The controller 110 may be implemented as a general-purpose processor "ATMega128L".

The RFID tag recognition unit 104 is a universal tag element "TRH031 MS", the voice IC 27 is a general-purpose integrated circuit "VS1053B", the communication unit 116 is a Wiznet universal communication element "W3150A +", the touch sensing unit ( 136 may be implemented as touch sensing elements “qt1081” respectively.

In FIG. 4, when a detection signal is generated from the touch detector 136 or the parking vehicle detector 1348, the LF module 142 of the key communicator 140 is activated. Although the figure shows that the sensing signal is directly applied to the LF module 142, the LF module 142 may be driven through the reader controller 110.

When the LF module 142 is activated, a low frequency signal of 125 kHz is transmitted to the radio channel (a). In addition, when the LF module 142 is activated, the UHF module 144 is also activated to be in the reception standby state.

When UHF data from the high frequency key 10 is received by the UHF module 144 via the radio channel b, the reader controller 110 generates parking position data. The parking position data generated at this time may be formatted in a configuration including an STX 71, a position ADD 72, an ID data 73, a CRC 74, and an ETX 75 as shown in FIG. 7. The parking position data generated by the reader controller 110 is transmitted to the line L10 through the communication unit 116. Accordingly, the parking location server 200 of FIG. 1 receives the parking location data.

When the parking position data is transmitted by wire, the communication unit 116 may have a communication interface of any one of RS232 / 422/485. However, when the parking position data is transmitted wirelessly, the communication interface may be Zigbee communication or Bluetooth communication.

Meanwhile, when the input of the confirmation key 130 is received by the reader controller 110 to confirm parking, the operation of transmitting the LF signal through the wireless channel a is performed by the LF module 142 which is activated again, and the UHF The module 144 goes into a waiting state for reception. When there is a reception of UHF data through the wireless channel b in the reception standby state or when an operation input through the operation input unit 134 is received, the reader controller 110 recognizes that a unique recognition code of the user is received. . When the unique identification code is received, the reader controller 110 searches the parking position data of the vehicle corresponding to the unique identification code. The search operation may be performed by the reader controller 110 searching the parking position data stored in the memory unit 112 or communicating with the parking position server 200 through the communication unit 116. It may include all receiving operations.

When the corresponding parking position data of the vehicle corresponding to the user who has requested parking confirmation is searched, the parking position information may be transmitted by text through the display unit 106 formed of a liquid crystal display. Alternatively, in the parking position information, a voice signal generated by the voice IC 27 may be transmitted through the speaker 129. Accordingly, the user may be guided to the parking area of the vehicle previously parked through the text, or may be guided to the parking area by sound.

On the other hand, in this case, the warning lights 121 installed in the corresponding parking area may be blinked to visually guide the parking position to make it easier to find the parked area.

The RFID tag recognition unit 104 receives a user unique identification code when the RFID passive tag unit 34 of FIG. 3 is tagged at a short range. That is, the RFID passive tag unit 34 is activated by receiving operating power from the received signal when a frequency signal of 13.56 MHz is received. In this case, since it is activated by an external power source, there is no battery power consumption in the passive RFID tag unit 34. In the IC chip memory mounted on the passive RFID tag unit 34, a unique identification code stored in advance is stored, which is wirelessly transmitted when the passive RFID tag unit 34 is activated.

Meanwhile, the radio channel c is utilized when the UHF module 20 of the high frequency key 10 of FIG. 3 is activated by the manipulation of the parking position generation key of the key input unit 36. That is, when the parking position generation key or the confirmation key is pressed, the switch 18 of FIG. 3 is closed so that the UHF module 20 and the control unit 28 are activated without the sensing operation of the wake-up detection unit 14.

When the emergency bell 120 is pressed when an emergency occurs for safety in the parking lot, emergency call data having different data contents from the parking position generation data is generated in the reader controller 110. The emergency call data is transmitted to the line L10 through the communication unit 116.

5 is an operation control flowchart according to a first example of the parking position reader of FIG. 1.

If a touch or vehicle detection signal is applied in step S50, the operation of activating the LF module and transmitting the LF signal is performed in step S51. The reader controller 110 activates the LF module 142 to generate parking position data when the output of the touch sensor 136 or the vehicle sensor 138 is present, and transmits a LF signal of 125KHz to a wireless channel (a Send through). Subsequently, in step S52, the UHF module 144 enters a reception standby state in response to the control of the reader controller 110. When the UHF data provided to the UHF module 20 of the high frequency key 10 is received in step S53 by the UHF module 144 in the key communication unit 140 via the wireless channel b, the operation in step S54 is executed. Step S54 is a step of generating and transmitting parking position data. Here, the parking position data may be generated as shown in FIG. 7.

The operation of parking position determination will now be described.

When the press of the parking confirmation key 130 is detected by the reader controller 110 in step S60, the operation of transmitting the LF signal and waiting to receive the UHF module is performed in step S61. That is, the reader controller 110 activates the LF module 142 and transmits a 125KHz LF signal through the wireless channel a to perform the parking position checking operation. In this case, the UHF module 144 enters a reception standby state under the control of the reader controller 110.

In step S62, when the UHF data is received through the wireless channel b or the key operation input is received through the operation input unit 134, step S63 is performed. In step S63, the parking position data is searched. Here, the reader controller 110 searches the parking location data stored by searching the memory unit 112, or communicates with the parking location server 200 through the communication unit 116 to be searched by the parking location server 200. The parking position data can simply be received.

Subsequently, step S64 is executed to transmit parking position information by text or voice. Accordingly, the user is informed of the parking area of the vehicle that has previously parked through the text, or is informed of the parking area through the sound.

On the other hand, in this case, the warning lights 121 installed in the corresponding parking area may be blinked to visually guide the parking position to make it easier to find the parked area.

In the description of FIG. 5, it has been described that the entry into the parking position checking mode is performed by pressing the parking confirmation key provided in the parking position reader in the parking lot again after the parking of the vehicle, but the present invention is not limited thereto. It may be performed by pressing a setting key or automatically by reading the user identification code information of the high frequency key under the linkage of the common entrance reader and the parking position reader of the parking lot entrance.

6 is an operation control flowchart according to a second example of the parking position reader of FIG. 1.

The control flow of FIG. 6 is performed when the UHF module 144 of FIG. 4 is always activated in a waiting state.

Therefore, in step S70, the UHF module enters a standby state. If UHF data is received in step S71, the operation in step S72 is executed. Step S72 is a step of generating and transmitting parking position data. This is substantially the same as step S54 of FIG. In step S73, when the copy function is applied, the operation of transmitting the parking position data using the high frequency key is performed. That is, when the copy key 132 of FIG. 4 is pressed after generation of the parking position data, the reader controller 110 wirelessly transmits the same data as the parking position data transmitted to the communication unit 116 through the UHF module 144. I can send it out. Accordingly, parking position data is stored in the memory unit 30 of the high frequency key 10. In this case the previously stored parking position data is erased or shifted to the last data storage subordinate order.

On the other hand, when the parking confirmation key is received in step S74, it is checked whether UHF data reception or operation input is received in step S75. Step S76 is performed when UHF data reception or operation input is received. In step S76, the parking position data is searched. Here, the steps S75, S76, and S77 of FIG. 6 correspond to the steps S62, S63, and S64 of FIG. 5, respectively, and the same control operation is performed between the corresponding steps.

Subsequently, step S77 is executed to transmit the parking position information by text or voice, and additionally, the warning light may blink. Accordingly, the user is informed of the parking area of the vehicle that has previously parked through the text, or is informed of the parking area through the sound. In addition, the blinking of the warning light makes it easy to find the parking area.

7 is an exemplary view illustrating the format of parking position data output from the parking position reader of FIG. 1. Referring to the drawings, the parking position data may be formatted in a configuration including the STX 71, the position ADD 72, ID data 73, CRC 74, ETX (75).

The parking location data can be operated in a total 12-byte code system, the STX 71 indicating the start area is 1 byte, the location address 72 indicating the area information area in which the parking location reader is installed is 1 byte, and the user's unique The area of the ID data 73 representing the recognition code is 8 bytes, the area of the CRC 74 for error correction and the area of the ETX 75 representing the end area can be allocated as 1 byte.

As described above, according to an embodiment of the present invention, the parking position data is generated without the tag operation of the radio frequency identification tag. In the end, users can park the location data by using the human body's touch, vehicle parking detection, or pressing the parking key installed on the high frequency key without having to tag the radio frequency identification tag embedded in the high frequency key to the parking location reader. Is increased.

In addition, since the parking confirmation can be easily pressed by pressing the parking confirmation key provided on the parking position reader or pressing the setting key of the high frequency key after the parking of the vehicle, the convenience of use is increased.

In the above description, the embodiments of the present invention have been described with reference to the drawings. . For example, in other cases, the components inside the parking position reader or the high frequency key may be implemented as other equivalent elements without departing from the technical spirit of the present invention.

Description of the Related Art [0002]
10: high frequency key
100: parking position reader
150: relay
200: parking location server

Claims (19)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete A key communication unit maintaining a standby state to receive a high frequency signal generated from the high frequency key;
Receiving the high-frequency signal to generate and transmit the parking position data indicating the parking area of the vehicle, and when entering the parking confirmation mode to search for the parking position information for the vehicle to generate and confirm the information visually or auditory With wealth,
Entering the parking confirmation mode is performed by pressing the parking confirmation key provided in the parking position reader or pressing the setting key of the high frequency key in the parking lot again after the parking of the vehicle, or interlocking of the common entrance reader and the parking position reader at the entrance of the parking lot. Parking position reader, characterized in that is performed automatically by reading the user identification code information of the high frequency key.

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