RU43988U1 - TELEMATIC SYSTEM TERMINAL WITH VIDEO IMAGE TRANSFER - Google Patents

Abstract

The utility model relates to the field of communication systems. To expand the functionality of the terminal, the device of the telematics system with the ability to transmit video images contains a microcontroller electrically interconnected with a transceiver, to which an audio interface unit is connected, with an input / output node, with power supply buses and with a video adapter node, to which are connected To video cameras, where К - integer.

Description

The utility model relates to communication systems, in particular, to a terminal device of a telematics system intended for the protection and monitoring of stationary objects, and can be used in monitoring systems for unauthorized entry into objects, monitoring systems for equipment parameters, etc.

The terminal device of the telematics system installed on a stationary object works by the principle of transmitting over the air to the dispatch center (DC) of the telematics system, upon request or by event, information about the state of the object received using external sensors and information received from video cameras connected to the device receiving over the air from the DC and executing commands to control the systems of the facility. In addition, the device allows you to establish a voice connection with the operator of the data center or another subscriber.

In terms of technical nature, the closest to the proposed one is a terminal device of a telematics system containing a microcontroller electrically interconnected with a navigation receiver, to which a first antenna is connected, a transceiver to which a second antenna and an audio interface unit are connected, and an input / output unit, power supply busbars (patent RF No. 2173888, Cl. G 08 B 25/08 of 09/10/2000).

The disadvantage of the considered terminal device is the inability to connect video cameras to receive video information and transmit this information to the data center.

The technical result is the expansion of functional

of opportunities.

The technical result is achieved in that the terminal device of the telematics system with the ability to transmit video images contains a microcontroller that is electrically interconnected with a transceiver, to which an audio interface unit is connected, with an input / output node, with power supply buses and with a video adapter node, to which are connected to video cameras, where K is an integer, in addition, the input-output node contains subnodes for interfacing with discrete-type sensors and actuators.

The essence of the technical solution lies in the fact that the introduction of a video adapter assembly provides the ability to receive and store information from K video cameras in the microcontroller, where K is an integer.

Comparison of the proposed model with the closest analogue allows us to claim compliance with the criterion of "novelty."

Preliminary tests and operating experience at specific facilities allow us to state the possibility of wide industrial use.

Figure 1 presents the structural diagram of the terminal device of the telematics system with the ability to transmit video images, figure 2 and 3 is a block diagram of the algorithm of the device.

The terminal device of the telematics system with the ability to transmit video images contains a microcontroller 1, a video adapter 2, a transceiver 3 of a GSM communication system, an audio interface unit 4, an input / output unit 5, a video camera 6-1 ... 6-K, where K is an integer, and buses 7 sources of 8 power supply.

A microphone can be connected to node 4 of the audio interface

phone (speaker).

The input-output node 5 may contain subnodes 9 and 10 for interfacing with discrete-type sensors and actuators, respectively.

The power supply buses 7 are connected to the corresponding terminals of the above-described nodes (not shown in FIG. 1), and both internal power supply 8 and external can be connected to these buses.

The microcontroller 1, electrically interconnected with the above nodes, controls the operation of these nodes and performs the algorithm of the multifunctional terminal device of the telematics system in accordance with the program located in the built-in read-only memory (ROM). The microcontroller 1 can be made, for example, in the form of a single-board computer ICOP6016 (company ICOP), having a form factor of 2.5 ".

Video adapter 2 provides the reception of a standard 1V video signal through separate channels from 6-1 ... 6-K video cameras, the selection of the current video information frame, compression of the video information frame according to the Wavelet algorithm, transmission of the compressed frame to the microcontroller via a standard serial or parallel interface. The video adapter can be made, for example, in the form of an embedded module of type МРР5 manufactured by OJSC "Ellipse", Zelenograd.

The transceiver 3 provides data reception / transmission via short messages (SMS), in direct connection mode, in GPRS mode, as well as voice connection in a GSM cellular communication system. The transceiver 3 can be performed, for example, in the form of an embedded GSM modem model G20 (Motorola).

The terminal device of the telematic system with the ability to transmit video images works as follows.

First, the device is configured, i.e. software configuration of the operating modes of various nodes and tuning of the functions performed. When configuring, it is also configured to work together with the dispatch center (DC) of the telematic system. Configuration can be performed through the node of the serial interface, which is part of the microcontroller 1, or over the air (through the transceiver 3). Further, changing the configuration parameters can be carried out during operation of the device.

The device is installed on a stationary object and connected to an external 12V DC power source.

Video adapter 2 sequentially receives video signals from standard video cameras 6-1 ... 6-K, generates the current frame of video information from the current video camera, and compresses the video information. The video information frame 2 compressed by the video adapter enters the microcontroller 1, which, according to the program loaded in the ROM, writes this data to the internal buffer memory, which has a ring organization and is designed to store 25-30 frames from each video camera. The frequency of recording video frames in the buffer memory is determined when configuring the device.

The microcontroller 1, when recording video frames in the buffer memory, additionally records the real-time value (in hours, minutes and seconds). Subsequently, on a command from the DC microcontroller

1 searches for video frames in the buffer memory for the required period of time and transmits these video frames to the transceiver 3 for transmission to the DC. If necessary, the microcontroller 1 can transmit video frames directly received from video adapter 2 to the DC (real-time mode).

The transceiver 3 provides the reception of messages from the data center, the transmission of messages and video frames to the data center and voice communication with the data center operator (subscriber). Messaging can be carried out via short message channels (SMS), video frames are transmitted in direct connection mode (Data Transfer) or GPRS. The format for presenting messages and the order of messaging is determined by the rules adopted for the telematic system. The control modes of the transceiver 3, the processing of incoming and the formation of outgoing messages are carried out by the microcontroller 1.

The device is connected to discrete-type sensors (with discrete outputs of the “on / off” type) through the subnode 9. Actuators are connected to the device through the subnode 10. The number of connected discrete-type sensors, actuators, as well as the technical options for the subnodes 9 and 10 are determined a specific implementation of the terminal device of the telematics system with the ability to transmit video images.

Subnodes 9 and 10 are electrically interconnected with microcontroller 1, which receives all the information from the sensors and which generates control signals (potential or pulse) by actuators.

When configuring a terminal device for sensors

triggering conditions (logical state or its change) are set, and for actuators - characteristics of output signals.

When a sensor is detected, the microcontroller 1 generates a corresponding outgoing message and transmits it through the transceiver 3 to the DC.

From the side of the DC, a command can be sent to the terminal device to activate or deactivate a specific actuator. In this case, the terminal device will generate a control signal for the corresponding actuator, the shape and duration of which is determined when configuring the terminal device.

To carry out voice exchange, a microphone and a telephone (speaker) are connected to the transceiver 3 through the node 4 of the audio interface.

Thus, the construction of a terminal device of a telematics system with the ability to transmit video images in the manner described above allows you to expand its functionality.

Claims (2)

1. The terminal device of a telematics system with the ability to transmit video images, characterized in that it contains a microcontroller, electrically interconnected with a transceiver, to which an audio interface unit is connected, with an input / output unit, with power supply buses and with a video adapter unit, to which video cameras are connected where K is an integer. 2. The terminal device according to claim 1, characterized in that the input-output node contains subnodes for interfacing with discrete-type sensors and actuators.