TWM658656U - Intelligent antenna electronic bridge device and security system using the same - Google Patents

Abstract

An intelligent antenna electronic bridge device is applied to the assurance device of a mobile device and is used to receive verification information from the mobile device within the near field communication range. The intelligent antenna electronic bridge device includes a near field communication tag and a microprocessor. The near field communication tag has an inductive coil antenna and a memory. The inductive coil antenna is used to sense the mobile device to generate an inductive current and start, and receive the verification information and write it into the memory, and generate a notification signal and send it out. The microprocessor is activated by the inductive current. When the notification signal is received, the verification information in the memory is accessed, and the verification information is encrypted and transmitted to the assurance device. Through the passive near field communication tag and its internal memory, the functions of energy saving and real-time transmission can be achieved.

Description

Intelligent antenna electronic bridge device and security system using the same

This invention involves the field of electronics, especially an intelligent antenna electronic bridge device and a security system using the same.

Currently, mobile devices, such as cars and motorcycles, have widely used near field communication (NFC) technology for locking and unlocking. The common method in the market is to install a near field communication reader (NFC reader) on the mobile device. The user uses the near field communication tag (NFC Tag) on the card or mobile device to generate induction at a close distance. The reader reads the information in the tag for judgment and then determines whether to unlock.

However, the NFC reader will basically maintain a periodic scan to confirm whether there are NFC tags in the surrounding environment. In addition to the high cost of installation, the energy consumption is also quite high.

Although tags have been installed on mobile devices recently, using mobile phone applications and near-field communication readers, the near-field communication tags themselves are passive and cannot send signals, which will cause near-field communication to be unable to synchronize and instantaneously ensure unlocking, requiring multi-stage operations, causing inconvenience to users.

In order to solve the problems faced by the prior art, a smart antenna electronic bridge device is provided, which is applied to the assurance device of the mobile device and is used to receive the verification information from the mobile device within the near field communication range. In some embodiments, the smart antenna electronic bridge device includes a near field communication tag and a microprocessor. The near field communication tag has an inductive coil antenna and a memory. The inductive coil antenna is used to sense the mobile device to generate an inductive current and start, and receive the verification information and write it into the memory, and generate a notification signal and send it out. The microprocessor is electrically connected to the near field communication tag and is activated by the inductive current. After receiving the notification signal, the verification information in the memory is accessed, and the verification information is encrypted and transmitted to the assurance device.

In some embodiments, the microprocessor further receives confirmation information from the assurance device, decrypts the confirmation information, and then transmits it to the mobile device via the induction coil antenna.

In some embodiments, the smart antenna electronic bridge device further includes a flexible circuit board, and the near field communication tag and the processor are installed on the flexible circuit board.

In more detail, in some embodiments, the smart antenna electronic bridge device further includes an electrical connector, which is mounted on a flexible circuit board and electrically connected to the microprocessor and the near field communication tag.

A security system is also provided herein, and the security system is applied to mobile equipment. In some embodiments, the security system includes an intelligent antenna electronic bridge device, a security host, and an electronic lock device. The intelligent antenna electronic bridge device includes a near-field communication tag and a microprocessor. The near-field communication tag has an induction coil antenna and a memory. The induction coil antenna is used to sense the mobile device to generate an induction current and start, and receive verification information from the mobile device, write the verification information into the memory, and generate and send a notification signal. The microprocessor is electrically connected to the near-field communication tag, and is activated by the induction current. When the notification signal is received, the verification information in the memory is accessed, and the verification information is encrypted and transmitted to the security host.

Ensure that the host is electrically connected to the intelligent antenna electronic bridge device, receive the encrypted verification information, and verify it. When the verification is successful, generate and send a release command. Electronic lock device Electrically connect to ensure that the host is electrically connected. When the release command is received, the electronic lock device is released.

In some embodiments, when the host authentication is successful, confirmation information is generated, the microprocessor receives the confirmation information, decrypts the confirmation information, and then transmits it to the mobile device through the induction coil antenna.

In some embodiments, when the host authentication fails, an error message is generated, the microprocessor receives the error message, decrypts the error message, and then transmits it to the mobile device via the inductive coil antenna.

In some embodiments, the intelligent antenna electronic bridge device is installed on the inner surface of the housing of the mobile device.

In some embodiments, the smart antenna electronic bridge device further includes a flexible circuit board, and the near field communication tag and the microprocessor are installed on the flexible circuit board.

In more detail, in some embodiments, the smart antenna electronic bridge device further includes a first electrical connector, which is installed on the flexible circuit board and electrically connected to the microprocessor and the near field communication tag, and ensures that the host includes a second electrical connector, and the first electrical connector is connected to the second electrical connector.

As described in the aforementioned embodiment, by adding memory to the near field communication tag and using the induction current to write the verification information, real-time information communication can be achieved in the near field communication state. In addition, since the smart antenna electronic bridge device is a passive device, it is activated only when it is activated by the induction current, which can greatly reduce energy consumption and also reduce the installation cost.

1: Intelligent antenna electronic bridge device

10: Near Field Communication Tag

11: Inductive coil antenna

13: Memory

20: Microprocessor

30: Flexible circuit board

40:Electrical connector

50: Ensure the host

55:Electrical connector

60: Electronic locking device

100: Ensure the system

200: Mobile equipment

300: Ensure the device

500: Mobile device

C: Induced current

D: Verification information

De: Encrypted verification information

E: Error message

Ed: Decryption error message

M:Confirm information

Md: Decryption confirmation information

R:Release command

I: Notification signal

Figure 1 is a top view of the smart antenna electronic bridge device.

Figure 2 is a block diagram of the smart antenna electronic bridge device.

Figure 3 is a block diagram of the assurance system.

Figure 4 is a schematic diagram of the assurance system.

In the following description, the terms "first", "second", and "third" are only used to distinguish one element, component, region, layer or part from another element, component, region, layer or part, rather than to indicate a necessary order of precedence. In addition, relative terms such as "lower" and "upper", "inner" and "outer" may be used herein to describe the relationship between one element and another element, and it should be understood that the relative terms are intended to include different orientations of the device other than the orientation shown in the figure. For example, if a device in an attached figure is flipped, the element described as being on the "lower" side of the other element will be oriented on the "upper" side of the other element. This only indicates a relative orientation relationship, not an absolute orientation relationship.

In the drawings, the width of some elements, regions, etc. is magnified for clarity. Throughout the specification, the same figure reference numerals represent the same elements. It should be understood that when an element is referred to as being "on" or "connected to" another element, it may be directly on or connected to another element, or an intermediate element may also exist. Conversely, when an element is referred to as being "directly on" or "directly connected to" another element, there are no intermediate elements.

FIG1 is a top view of the smart antenna electronic bridge device. FIG2 is a block diagram of the smart antenna electronic bridge device. As shown in FIG1 and FIG2, the smart antenna electronic bridge device 1 is used to bridge the mobile device 300 and the mobile device 500, such as a mobile phone. The smart antenna electronic bridge device 1 can receive the verification information D from the mobile device 500 within the near field communication range. In some embodiments, the smart antenna electronic bridge device 1 includes a near field communication tag 10 and a microprocessor 20. The NFC tag 10 has an inductive coil antenna 11 and a memory 13. The inductive coil antenna 11 is used to sense the mobile device 500 to generate an inductive current C to activate, receive the verification information D and write it into the memory 13, and generate and send out a notification signal I. The microprocessor 20 is electrically connected to the NFC tag 10 and is activated by the inductive current C. After receiving the notification signal I, it accesses the verification information D in the memory 13, encrypts the verification information D into encrypted verification information De, and transmits it to the assurance device 300 for verification.

Here, by using a passive NFC tag 10, the NFC tag 10 and the microprocessor 20 are activated only when sensing within the NFC range, which can greatly save overall energy consumption. Furthermore, by setting a memory 13 in the NFC tag 10 and cooperating with the microprocessor 20, information can be transmitted in real time and synchronously without interrupting the NFC.

Referring to FIG. 1 again, the smart antenna electronic bridge device 1 further includes a flexible circuit board 30 and an electrical connector 40. The near field communication tag 10, the microprocessor 20 and the electrical connector 40 are mounted on the flexible circuit board 30. The near field communication tag 10, the microprocessor 20 and the electrical connector 40 are electrically connected to each other through the flexible circuit board 30 and can switch high/low potentials through the induction current C to achieve actuation and transmission of the notification signal I. The electrical connector 40 can be connected to the ensuring device 300.

FIG3 is a block diagram of the security system. FIG4 is a schematic diagram of the security system. As shown in FIG3 and FIG4, the security system 100 is applied to a mobile device 200. In some embodiments, the security system 100 includes an intelligent antenna electronic bridge device 1, a security host 50, and an electronic lock device 60. More specifically, as shown in FIG4, the intelligent antenna electronic bridge device 1 is mainly installed on the inner surface of the housing of the mobile device 200, and the security host 50 and the electronic lock device 60 constitute the aforementioned security device 300.

The structure of the intelligent antenna electronic bridge device 1 is the same as the above, receiving the verification information D from the automatic device 500, wherein the verification information D is written into the memory 13, the microprocessor 20 accesses the verification information D in the memory 13, and encrypts the verification information D into the encrypted verification information De and transmits it to the security host 50.

Ensure that the host 50 is electrically connected to the intelligent antenna electronic bridge device 1, and performs verification after receiving the encrypted verification information De. When the verification is successful, a release command R is generated and sent out. The electronic lock device 60 is electrically connected to the host 50. When the release command R is received, the electronic lock device 60 is released, and the unlocking function is achieved, and the mobile device 200 can be activated.

Furthermore, in some embodiments, when the host 50 is successfully authenticated, confirmation information M is generated, the microprocessor 20 receives the confirmation information M, decrypts the confirmation information M into a decrypted confirmation information Md, and then transmits it to the mobile device 500 through the induction coil antenna 11. When the host 50 is authenticated unsuccessfully, error information E is generated, the microprocessor 20 receives the error information E, decrypts the error information E into a decrypted error information Ed, and then transmits it to the mobile device 500 through the induction coil antenna 11. However, the above-mentioned steps need to be performed within the range of near field communication.

The host 50 can also use the electrical connector 55 on it to directly or indirectly connect with the electrical connector 40 of the intelligent antenna electronic bridge device 1, so as to ensure the electrical connection and signal communication between the host 50 and the intelligent antenna electronic bridge device 1.

In summary, by adding memory 13 to the near field communication tag 10 and using the induction current C to write the verification information D, real-time information communication can be achieved in the state of near field communication. In addition, since the smart antenna electronic bridge device 1 is a passive device, it is activated only when it is subjected to the induction current C, which can greatly reduce energy consumption and also reduce the installation cost.

1: Intelligent antenna electronic bridge device

10: Near Field Communication Tag

11: Inductive coil antenna

13: Memory

20: Microprocessor

40:Electrical connector

500: Mobile device

C: Induced current

D: Verification information

De: Encrypted verification information

Claims (10)

An intelligent antenna electronic bridge device is applied to a security device of a mobile tool and is used to receive a verification information from a mobile device in a near field communication range, comprising: a near field communication tag, having an inductive coil antenna and a memory, the inductive coil antenna is used to sense the mobile device to generate an inductive current to start, receive the verification information and write it into the memory, and generate a notification signal and send it out; and a microprocessor, electrically connected to the near field communication tag, activated by the inductive current, accesses the verification information in the memory after receiving the notification signal, and encrypts the verification information and transmits it to the security device. As described in claim 1, the microprocessor further receives a confirmation message from the assurance device, decrypts the confirmation message, and then transmits it to the mobile device via the induction coil antenna. The smart antenna electronic bridge device as described in claim 1, wherein the smart antenna electronic bridge device further includes a flexible circuit board, and the near field communication tag and the microprocessor are installed on the flexible circuit board. The smart antenna electronic bridge device as described in claim 3, wherein the smart antenna electronic bridge device further includes an electrical connector, which is installed on the flexible circuit board and is electrically connected to the microprocessor and the near field communication tag. A guarantee system, applied to a mobile device, comprises: An intelligent antenna electronic bridge device, comprising: A near field communication tag, having an inductive coil antenna and a memory, the inductive coil antenna is used to sense a mobile device to generate an inductive current to start, and receive a verification information from the mobile device, and write the verification information into the memory, and generate a notification signal and send it out; and A microprocessor, electrically connected to the near field communication tag, activated by the inductive current, accesses the verification information in the memory after receiving the notification signal, and encrypts the verification information and transmits it out; A security host, electrically connected to the smart antenna electronic bridge device, receives the encrypted verification information and performs verification. When the verification is successful, a release command is generated and sent out; and an electronic lock device, electrically connected to the security host, releases the electronic lock device when the release command is received. As described in claim 5, the assurance system generates a confirmation message when the assurance host is successfully authenticated, the microprocessor receives the confirmation message, decrypts the confirmation message, and then transmits it to the mobile device via the induction coil antenna. The assurance system as described in claim 5, wherein when the assurance host authentication fails, an error message is generated, the microprocessor receives the error message, decrypts the error message, and then transmits it to the mobile device via the induction coil antenna. A ensuring system as described in claim 5, wherein the intelligent antenna electronic bridge device is installed on the inner surface of a shell of the mobile device. The ensuring system as described in claim 5, wherein the intelligent antenna electronic bridge device further includes a flexible circuit board, and the near field communication tag and the microprocessor are installed on the flexible circuit board. As described in claim 9, the ensuring system, wherein the intelligent antenna electronic bridge device further includes a first electrical connector, which is installed on the flexible circuit board and is electrically connected to the microprocessor and the near-field communication tag, and the ensuring host includes a second electrical connector, which is connected to the second electrical connector.

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