CN110161723B - Mobile monitoring and identification glasses - Google Patents

Abstract

The embodiment of the present invention discloses a mobile monitoring identification glasses, wherein one end of the glasses leg in contact with the lens extends downward to form a cavity inside the glasses leg, a lens gap is formed between the lenses, the middle part of the frame extends toward the lens gap to form a collection part, a wiring channel is formed inside the frame, the collection part is connected with a data line, and the data line extends from the wiring channel through the hinge connection between the frame and the glasses leg to the inside of the cavity; a microprocessor, a camera module, a radio frequency transceiver, a radio frequency power amplifier, a heat sink, a SIM module and a power module are arranged inside the cavity; the collection part is connected to the camera module via a data line, and the camera module takes images; the radio frequency transceiver transmits image data; and the SIM module realizes the identity recognition of the monitoring identification glasses. The present invention can realize the real-time video transmission function, can transmit the on-site video to the command center in real time, realize all-round mobile monitoring, reduce the recognition error rate, prevent the escape of lawbreakers, and ensure social security.

Description

Mobile monitoring and identifying glasses

Technical Field

The embodiment of the invention relates to the technical field of glasses, in particular to a pair of mobile monitoring and identifying glasses.

Background

Face recognition technology is widely used in security industry at present, and main application forms are divided into two types from the technical level, one type is 1:1, comparing, the form is mainly applied to places needing real-name verification such as stations, wharfs and airports, namely verifying whether identity documents are consistent with a holder or not; the other is 1: n compares, and this kind of application is mainly used in "safe city", "bright as snow engineering" scheduling project, adopts the mounting means of fixed camera, directly realizes face snapshot, discernment or carries out face identification through the form of video transmission at the server side at the camera end.

At present, face recognition is generally achieved by installing a fixed camera, and due to the fact that the installation position is fixed, the acquisition range is limited, or no proper installation position exists, and installation conditions are not met. Face recognition has specific requirements (the angles of the side faces are within 35 degrees up and down), so that the phenomenon of false recognition or no recognition can occur for faces with angles which are not in accordance with the requirements, thereby causing the occurrence of monitoring dead angles, causing high-risk specific crowds such as criminals to escape, and causing great danger to society.

Disclosure of Invention

Therefore, the embodiment of the invention provides the mobile monitoring and identifying glasses, which solves the problems that the traditional scheme has monitoring dead angles or cannot be identified due to the range limitation of the fixed cameras.

In order to achieve the above object, the embodiment of the present invention provides the following technical solutions: the utility model provides a mobile monitoring discernment glasses, includes lens, glasses leg and picture frame, the one end that the glasses leg contacted with the lens extends downwards and makes the inside cavity that is formed with of glasses leg, be equipped with the radiator in the cavity, the radiator disposes the heat dissipation through-hole, the heat dissipation through-hole is located the upper and lower both sides of cavity;

The end part of the glasses frame is hinged with the glasses legs, the glasses frame is connected with the lenses, a lens gap is formed between the lenses, the middle part of the glasses frame extends towards the lens gap to form a collecting part, a wiring channel is formed in the glasses frame, the collecting part is connected with a data wire, and the data wire extends from the wiring channel to the inside of the cavity through the hinged joint of the glasses frame and the glasses legs;

The cavity is internally provided with a microprocessor, a camera module, a radio frequency transceiver, a radio frequency power amplifier, a SIM module and a power supply module; the microprocessor adopts PSL09; the camera module establishes a connection relation with the microprocessor, the acquisition part is connected with the camera module through the data line, and the camera module is used for monitoring and identifying glasses to shoot images; the radio frequency transceiver establishes a connection relation with the microprocessor, the radio frequency transceiver adopts MRF49XA, the radio frequency power amplifier establishes a connection relation with the radio frequency transceiver, and the radio frequency transceiver is used for monitoring and identifying glasses to transmit image data; the radiator establishes a connection relation with the microprocessor, and is used for monitoring and identifying the glasses to radiate heat; the SIM module establishes a connection relation with the microprocessor, and is used for monitoring and identifying the identity of the glasses; the power module establishes a connection relation with the microprocessor, and is used for monitoring and identifying power supply of the glasses.

As the preferred scheme of mobile monitoring discernment glasses, the data line is integrated with the FPC flexible sheet, the FPC flexible sheet is followed walk the line passageway warp the hinge junction of picture frame and glasses leg extends to inside the cavity, the FPC flexible sheet follows picture frame and glasses leg fold and expand.

As a preferable scheme of the mobile monitoring and identifying glasses, the acquisition part adopts an optical zoom camera; the radio frequency power amplifier is connected with an antenna.

As a preferred scheme of the mobile monitoring and identifying glasses, the SIM module is configured with a 3G chip, a 4G chip or a 5G chip.

As the preferable scheme of the mobile monitoring and identifying glasses, the power module is provided with a lithium battery, a USB charging interface and a start key.

As the preferable scheme of the mobile monitoring and identifying glasses, the mobile monitoring and identifying glasses further comprise a storage module, wherein the storage module is provided with a Flash memory and is used for storing images acquired by the camera module.

As the preferable scheme of mobile monitoring discernment glasses, still include display module, display module disposes OLED display screen, display module is used for showing the image that monitoring discernment glasses shot, OLED display screen integration is in the middle part of picture frame.

As the preferred scheme of mobile monitoring discernment glasses, still include audio module, audio module disposes the speaker, the speaker is equipped with the sound wave opening, the sound wave opening distributes the lateral part in cavity.

As the optimal scheme of mobile monitoring discernment glasses, the outside of heat dissipation opening is equipped with flexible baffle, flexible baffle embedding the inside of glasses leg, flexible baffle is used for changing the hot air flow direction of heat dissipation opening.

The embodiment of the invention has the following advantages: one end of each glasses leg, which is contacted with each lens, extends downwards to enable a cavity to be formed inside each glasses leg, a lens gap is formed between the lenses, the middle part of each glasses frame extends towards the corresponding lens gap to form a collecting part, a wiring channel is formed inside each glasses frame, the collecting part is connected with a data wire, and the data wire extends from the wiring channel to the inside of the cavity through a hinged joint of each glasses frame and each glasses leg; the inside of the cavity is provided with a microprocessor, a camera module, a radio frequency transceiver, a radio frequency power amplifier, a radiator, a SIM module and a power module; the acquisition part is connected with the camera module through a data line, and the camera module shoots images; the radio frequency transceiver transmits image data; the SIM module realizes the identity recognition of the monitoring recognition glasses. The invention can realize the video real-time transmission function, can transmit the field video to the command center in real time under the modes of daily patrol, bayonet monitoring or case field, traffic control and the like, plays the role of moving a camera, realizes the omnibearing mobile monitoring, reduces the recognition error rate, avoids lawless persons from escaping, and ensures the social security.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It will be apparent to those of ordinary skill in the art that the drawings in the following description are exemplary only and that other implementations can be obtained from the extensions of the drawings provided without inventive effort.

The structures, proportions, sizes, etc. shown in the present specification are shown only for the purposes of illustration and description, and are not intended to limit the scope of the invention, which is defined by the claims, so that any structural modifications, changes in proportions, or adjustments of sizes, which do not affect the efficacy or the achievement of the present invention, should fall within the ambit of the technical disclosure.

Fig. 1 is a schematic diagram of a structure of a pair of mobile monitoring and identifying glasses according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a structure of a pair of mobile monitoring and identifying glasses at another view angle according to an embodiment of the present invention;

Fig. 3 is a schematic diagram of an internal structure of a glasses frame for mobile monitoring and identification according to an embodiment of the present invention;

Fig. 4 is a schematic diagram of a circuit structure of a mobile monitoring and identifying glasses provided in an embodiment of the present invention;

in the figure: 1. a lens; 2. spectacle legs; 3. a frame; 4. a cavity; 5. lens gap; 6. an acquisition unit; 7. a routing channel; 8. a data line; 9. a microprocessor; 10. a camera module; 11. a radio frequency transceiver; 12. a radio frequency power amplifier; 13. a SIM module; 14. a power module; 15. an antenna; 16. a lithium battery; 17. a USB charging interface; 18. a start key; 19. a storage module; 20. a Flash memory; 21. a display module; 22. an OLED display screen; 23. an audio module; 24. a speaker; 25. a sound wave port; 26. a heat sink; 27. a heat dissipation through hole; 28. and a telescopic baffle.

Detailed Description

Other advantages and advantages of the present invention will become apparent to those skilled in the art from the following detailed description, which, by way of illustration, is to be read in connection with certain specific embodiments, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1,2,3 and 4, there is provided a pair of mobile monitoring and identifying glasses, the monitoring glasses include a lens 1, a glasses leg 2 and a glasses frame 3, one end of the glasses leg 2 contacting with the lens 1 extends downwards to form a cavity 4 inside the glasses leg 2, a radiator 26 is arranged in the cavity 4, the radiator 26 is provided with a heat dissipation through hole 27, and the heat dissipation through holes 27 are located on the upper side and the lower side of the cavity 4. The tip of picture frame 3 with glasses leg 2 hinge connection, picture frame 3 with lens 1 is connected, is formed with lens clearance 5 between the lens 1, the middle part of picture frame 3 to lens clearance 5 extends and is formed with collection portion 6, and the inside of picture frame 3 is formed with and walks line passageway 7, collection portion 6 is connected with data line 8, data line 8 follow walk line passageway 7 warp picture frame 3 with glasses leg 2 hinge junction extends to inside the cavity 4. The cavity 4 is internally provided with a microprocessor 9, a camera module 10, a radio frequency transceiver 11, a radio frequency power amplifier 12, a SIM module 13 and a power module 14; the microprocessor 9 adopts PSL09; the camera module 10 establishes a connection relationship with the microprocessor 9, the acquisition part 6 is connected with the camera module 10 through the data line 8, and the camera module 10 is used for monitoring and identifying glasses to shoot images; the radio frequency transceiver 11 establishes a connection relationship with the microprocessor 9, the radio frequency transceiver 11 adopts MRF49XA, the radio frequency power amplifier 12 establishes a connection relationship with the radio frequency transceiver 11, and the radio frequency transceiver 11 is used for monitoring and identifying glasses for image data transmission; the radiator 26 establishes a connection relationship with the microprocessor 9, and the radiator 26 is used for monitoring and identifying the glasses to radiate heat; the SIM module 13 establishes a connection relation with the microprocessor 9, and the SIM module 13 is used for monitoring and identifying the identity of the glasses; the power module 14 establishes a connection relationship with the microprocessor 9, and the power module 14 is used for monitoring and identifying the power supply of the glasses.

Specifically, the PSL09 is powered by a low-voltage intel pentium M1.4ghz processor, so as to meet the low-power consumption application requirement of the monitoring and identification glasses, and the PSL09 can use an ultra-low-voltage intel siren M processor. PSL09 supports 33/66MHzPCI bus, 333MHzDDRSDRAM with one VGA interface and 256Mbytes of optional ECC. PSL09 provides connectivity for a wide range of embedded applications, and is equipped with four USB2.0 ports, two serial ATA channels and two fast ethernet ports.

Specifically, the MRF49XA radio frequency transceiver 11 supports a sub-GHz wireless protocol, is compatible with a 4-wire serial peripheral interface and is compatible with an I/O interface of CMOS/TTL, is suitable for clock and reset signals of a singlechip, integrates a 10MHz oscillating circuit, integrates a low battery voltage detector, supports an energy-saving mode and has working voltage of 2.2V-3.8V. Low current consumption, receive (RX) mode: 11mA; transmission (TX) mode: 15mA; sleep mode: 0.3mA. A 16 pin TSSOP package is used.

In one embodiment of the mobile monitoring and identifying glasses, the data line 8 is integrated with an FPC ((Flexible Printed Circuit) flexible board, the FPC flexible board extends from the wiring channel 7 to the inside of the cavity 4 through the hinge joint of the glasses frame 3 and the glasses legs 2, and the FPC flexible board is folded and unfolded along with the glasses frame 3 and the glasses legs 2. The FPC flexible board adopts a printed circuit made of flexible insulating base materials, can be freely bent, rolled and folded, can be randomly arranged according to the space layout requirement, and can be randomly moved and stretched in a three-dimensional space, so that the effective connection of the acquisition part 6 at the front end of the glasses frame 3 and the camera module 10 inside the glasses legs 2 is ensured on the premise that the glasses legs 2 and the glasses frame 3 are folded and unfolded.

In one embodiment of the mobile monitoring and identifying glasses, the collecting part 6 adopts an optical zoom camera; the radio frequency power amplifier 12 is connected to an antenna 15. The rf power amplifier 12 is an electronic circuit that takes into account issues such as output power, excitation level, power consumption, distortion, efficiency, size and weight. The radio frequency power amplifier 12 circuit includes transistors, bias and stabilizing circuits, and input-output matching circuits. The range of the rf power amplifier 12 output power may be as small as mW, as large as a few kW. The antenna 15 enables transmission and reception of remote data signals.

In one embodiment of the mobile monitoring and identification glasses, the SIM module 13 is configured with a 3G chip, a 4G chip or a 5G chip. The 5G chip can adopt Balong Gs 5000 which are small in size and high in integration level, multiple network systems of 2G, 3G, 4G and 5G can be realized in a single chip, balong 5000 can realize 4.6Gbps in Sub-6GHz (low frequency band, 5G main frequency band) and can reach 6.5Gbps in millimeter wave (high frequency band, 5G extension frequency band) frequency band, and the speed is 10 times of the speed which can be experienced by 4G LTE.

In one embodiment of the mobile monitoring identification glasses, the power module 14 is configured with a lithium battery 16, a USB charging interface 17, and a power on key 18. The lithium battery 16 is used for providing a power source, the USB charging interface 17 is used for charging the lithium battery 16, and the start-up key 18 is used for switching on the power supply of the power module 14. The camera module 10 further comprises a storage module 19, wherein the storage module 19 is configured with a Flash memory 20, and the storage module 19 is used for storing images acquired by the camera module 10. The display module 21 is configured with an OLED display screen 22, the display module 21 is used for displaying images shot by the monitoring and identification glasses, and the OLED display screen 22 is integrated in the middle of the glasses frame 3. The device further comprises an audio module 23, wherein the audio module 23 is provided with a loudspeaker 24, the loudspeaker 24 is provided with sound wave through holes 25, and the sound wave through holes 25 are distributed on the side part of the cavity 4. The OLED display 22 used in this embodiment is a display made of organic light emitting diodes, and has a self-emitting organic light emitting diode, which does not need a backlight source, and has high contrast ratio, thin thickness, wide viewing angle, fast reaction speed, and wide application temperature range, and can be used for flexible panels. The circuit has the advantages of realizing miniaturization of the whole structure of the circuit, facilitating long-time wearing of users, being strong in wearing comfort, good in heat dissipation performance, not easy to be perceived by lawbreakers and beneficial to evidence collection.

In one embodiment of the mobile monitoring and identifying glasses, a telescopic baffle 28 is arranged at the outer side of the heat dissipation opening 27, the telescopic baffle 28 is embedded into the glasses leg 2, and the telescopic baffle 28 is used for changing the hot air flow direction of the heat dissipation opening 27. In cold weather, the telescopic baffle 28 can be pulled out to change the direction of the hot air flow of the heat dissipation port 27, and the hot air flow is guided to the head of a wearer, and the temple position is optimal, so that the warming effect of one thread is brought to the worker who enforces law in severe cold. In hot weather, the telescopic baffle 28 is hidden in the glasses legs 2, so that the shielding of hot air flow is avoided, and the temperature is better emitted. The retractable barrier 28 makes the mobile monitoring identification spectacles more human-friendly.

According to the embodiment of the invention, one end of the glasses leg 2, which is in contact with the lenses 1, is extended downwards to form a cavity 4 inside the glasses leg 2, a lens gap 5 is formed between the lenses 1, the middle part of the glasses frame 3 extends towards the lens gap 5 to form a collecting part 6, a wiring channel 7 is formed inside the glasses frame 3, the collecting part 6 is connected with a data wire 8, and the data wire 8 extends from the wiring channel 7 to the cavity 4 through a hinge joint part of the glasses frame 3 and the glasses leg 2; the cavity 4 is internally provided with a microprocessor 9, a camera module 10, a radio frequency transceiver 11, a radio frequency power amplifier 12, a radiator 26, a SIM module 13 and a power module 14; the acquisition part 6 is connected with the camera module 10 through the data line 8, and the camera module 10 shoots images; the radio frequency transceiver 11 performs image data transmission; the SIM module 13 enables the identification of the monitoring identification glasses. The invention can realize the video real-time transmission function, can transmit the field video to the command center in real time under the modes of daily patrol, bayonet monitoring or case field, traffic control and the like, plays the role of moving a camera, realizes the omnibearing mobile monitoring, reduces the recognition error rate, avoids lawless persons from escaping, and ensures the social security.

While the invention has been described in detail in the foregoing general description and specific examples, it will be apparent to those skilled in the art that modifications and improvements can be made thereto. Accordingly, such modifications or improvements may be made without departing from the spirit of the invention and are intended to be within the scope of the invention as claimed.

Claims (6)

1. A mobile monitoring identification glasses, comprising a lens (1), a temple (2) and a frame (3), wherein one end of the temple (2) in contact with the lens (1) extends downward so that a cavity (4) is formed inside the temple (2), characterized in that an end of the frame (3) is hingedly connected to the temple (2), the frame (3) is connected to the lens (1), a lens gap (5) is formed between the lenses (1), a collection portion (6) is formed in the middle of the frame (3) extending toward the lens gap (5), a wiring channel (7) is formed inside the frame (3), the collection portion (6) is connected to a data line (8), and the data line (8) extends from the wiring channel (7) through the hinged connection between the frame (3) and the temple (2) to the inside of the cavity (4); The cavity (4) is provided with a microprocessor (9), a camera module (10), a radio frequency transceiver (11), a radio frequency power amplifier (12), a SIM module (13) and a power module (14); the camera module (10) is connected to the microprocessor (9); the acquisition unit (6) is connected to the camera module (10) via the data line (8); the camera module (10) is used to monitor the identification glasses for image capture; the radio frequency transceiver (11) is connected to the microprocessor (9); the radio frequency power amplifier (12) is connected to the radio frequency transceiver (11); the radio frequency transceiver (11) is used to monitor the identification glasses for image data transmission; the SIM module (13) is connected to the microprocessor (9); the SIM module (13) is used to monitor the identity recognition of the identification glasses; the power module (14) is connected to the microprocessor (9); the power module (14) is used to monitor the power supply of the identification glasses; The acquisition unit (6) uses an optical zoom camera; the radio frequency power amplifier (12) is connected to an antenna (15); a heat sink (26) is provided in the cavity (4), and the heat sink (26) is provided with a heat dissipation opening (27), and the heat dissipation opening (27) is located at the upper and lower sides of the cavity (4); the heat sink (26) is connected to the microprocessor (9), and the heat sink (26) is used to monitor and identify the glasses for heat dissipation; a telescopic baffle (28) is provided on the outer side of the heat dissipation opening (27), and the telescopic baffle (28) is embedded in the interior of the glasses leg (2), and the telescopic baffle (28) is used to change the direction of the hot air flow of the heat dissipation opening (27); It also comprises a display module (21), wherein the display module (21) is provided with an OLED display screen (22), and the display module (21) is used to display images captured by the monitoring identification glasses, and the OLED display screen (22) is integrated in the middle of the frame (3). 2. The mobile monitoring identification glasses according to claim 1 are characterized in that the data cable (8) is integrated with an FPC flexible board, and the FPC flexible board extends from the wiring channel (7) through the hinge connection between the frame (3) and the temple (2) to the inside of the cavity (4), and the FPC flexible board follows the frame (3) and the temple (2) to fold and unfold. 3. The mobile monitoring and identification glasses according to claim 1, characterized in that the SIM module (13) is configured with a 3G chip, a 4G chip or a 5G chip. 4. The mobile monitoring identification glasses according to claim 1, characterized in that the power module (14) is equipped with a lithium battery (16), a USB charging interface (17) and a power button (18). 5. The mobile monitoring identification glasses according to claim 1 are characterized in that they also include a storage module (19), wherein the storage module (19) is configured with a Flash memory (20), and the storage module (19) is used to store images collected by the camera module (10). 6. The mobile monitoring identification glasses according to claim 1 are characterized in that they also include an audio module (23), wherein the audio module (23) is configured with a speaker (24), and the speaker (24) is provided with a sound wave outlet (25), and the sound wave outlet (25) is distributed on the side of the cavity (4).