RU130098U1 - SMART HOUSE SYSTEM WITH INTELLECTUAL ADAPTIVE INPUT / OUTPUT - Google Patents

Abstract

The Smart Home system with intelligent adaptive input / output, containing N groups of sensors, N groups of actuators and a control unit consisting of a microprocessor, characterized in that it additionally contains an equipment profile generator that queries existing equipment profiles, generates and transfers generated equipment profiles to the local and global storage of equipment profiles, local storage of equipment profiles, equipment adapter that unifies pairs equipment meters of different standards and different manufacturers without making any changes to the Smart Home system itself, digital-to-analog converter, analog-to-digital converter, global storage of equipment profiles, N input-output modules consisting of a power key unit, signal level amplifier-converter and switch , and the global storage of equipment profiles is made in the form of storage on a remote server.

Description

The utility model relates primarily to microprocessor-based systems for controlling power loads and polling sensors, and, in particular, can be used in devices for automating buildings and industrial processes.

A known relay protection and automation system containing N processing devices, N communication nodes, a microprocessor converter. [1] The known system, in particular, is widely used to automate the process of collecting information about the state of inputs, connections and switches of an object of control and management, processing this information and transmitting it to operational personnel.

The main significant disadvantage of the known system is the inability to connect actuators to it, since the system lacks devices for interfacing with actuators.

Closest to the claimed utility model is the microprocessor information management system "Smart Home". The system contains N groups of sensors, N groups of actuators and a control unit consisting of a microprocessor having a first group of inputs and outputs, which is the first group of inputs and outputs of the control unit and a group of inputs and outputs of the system for connecting to an external computer, as well as a second group inputs and outputs, while the device has N processing and communication units and a power supply unit included in the control unit and the output of which is the power supply output of the control unit and connected to the power inputs of N processing units ki and communications, moreover, the group of outputs of each of the N processing and communication units is connected to the group of inputs of the corresponding groups of actuators, the group of inputs is connected to the group of inputs of the corresponding groups of sensors, and the group of inputs and outputs is connected to the second group of inputs. [2]

The main significant drawback of the known system (prototype) is the inability to connect sensors and actuators to it having different potentials of logical levels (for example, if a logical zero corresponds to a voltage range from 0 to 7 volts, a logical unit from 9 to 15 volts) and different formats analog and digital input and output signals, such as pulse meters, delayed dry contact sensors, signal coding interfaces (e.g. 1-wire), signal modulation interfaces proportional to ble high load proportional sensor outputs, wherein the signal value is linearly related to the magnitude of the measured physical quantity or characteristics. Due to the lack of support for the arbitrary shape, level and logic of the input and output signals, the well-known analogue has a narrow scope, and systems based on it are of high cost, since they do not allow the use of sensors and actuators of various manufacturers on the market meeting various standards.

The main task solved by the claimed utility model is: a substantial expansion of the scope and reduction of the cost of implementing the Smart Home system by expanding the range and assortment of sensors and actuators connected to it from various manufacturers and meeting various input and / or output signal standards in its form , level and logic of work without the need to make changes to the system itself. The problem is solved in a utility model by introducing into the system a generator of equipment profiles, a local storage of equipment profiles, an equipment adapter, a digital-to-analog converter, an analog-to-digital converter, a global storage of equipment profiles, N input / output modules consisting of a block of power keys , an amplifier-converter of signal level and switch, and also due to the fact that the global storage of equipment profiles is made in the form of storage on a remote server.

Neither from the patent technical literature, nor from the practice of designing microprocessor-based power load control systems and polling sensors is known about its design and, in particular, the expansion of the range and range of sensors and actuators connected to the Smart Home system from various manufacturers and meeting various standards input and / or output signal in its form, level and logic of operation without the need to make changes to the system itself. The conclusion that the claimed technical solution meets the criterion of "novelty" is valid.

The combination of new and common for the prototype and the claimed technical solution of the essential features can be implemented many times. At the same time, the same effect is achieved and the main task posed by the utility model described above is solved. A legitimate conclusion should be drawn on the conformity of the declared decision with the criterion of “industrial applicability”. Testing of the proposed solution as a utility model was carried out as part of a building automation system in the test laboratory of Bravo Motors LLC.

The essence of the claimed technical solution is illustrated by the diagram of the components of the Smart Home system with intelligent adaptive input / output. The system consists of a control unit 1, consisting of a microprocessor 2 and N input-output modules 3 and a global storage of equipment profiles 13, while the microprocessor 3 includes an equipment adapter 4, a local storage of equipment profiles 5, a generator of equipment profiles 6, digital-to-analog converter 7, analog-to-digital converter 8, and input-output module 3 consists of a block of power switches 9, an amplifier-converter of signal level 10, switch 11, and a universal contact pair 15. Additionally, s remote server 12, communication channels between the remote server and the control unit 14, a group of sensors 16 and actuators 17 group.

The Smart Home system with intelligent adaptive input / output works as follows. A sensor from a group of sensors 16 or an actuator from a group of actuators 17 is connected to a universal contact pair 15. A user, which can be both the end user of the Smart Home system and the tuner (integrator), sets the equipment profile generator 6 to specify whether the connected equipment is a sensor or an actuator, and also sets its name (trademark and model). The equipment profile generator makes a request to the local storage of equipment profiles 5 about the profile of the connected device corresponding to the specified name. If there is no profile of the specified device in the local storage of equipment profiles, it makes a request through the communication channels 14 to the global storage of equipment profiles 13 located on the remote server 12.

If the global storage of equipment profiles contains the profile of the necessary equipment, this profile is sent back to the control unit 1 and stored in the local storage of equipment profiles. If the global repository of equipment profiles does not contain the profile of the necessary equipment, a negative response is also sent to the control unit, to the local repository of equipment profiles. The local storage of equipment profiles, in turn, returns to the equipment profile generator either the profile of the required equipment or information that the required profile is not contained in either the local or global storage of equipment profiles.

If the profile of the required equipment is found, the operation of the equipment profile generator is terminated. If the profile of the required equipment is not found, the profile generator prompts the user to set the basic parameters of the equipment connected to the universal contact pair.

For actuators, the parameters include the type and shape of the signal (direct, alternating current or pulse signal, maximum and minimum permissible voltages and currents), a range of logical level values for discrete signals, scaling factors for proportional signals, the presence or absence of signal inversion, and also other parameters necessary for the correct operation of the actuator. For sensors, parameters include the type and shape of the signal, the measured physical quantity or complex parameter associated with the signal, the nature of the relationship between the measured quantity and the dependent physical quantity, voltage and current ranges, response threshold, sensitivity, signal processing function (e.g., pulse counter) , as well as other parameters necessary for the correct operation of the actuator. For complex waveforms and signals requiring post-processing, the equipment profile generator can receive a calibration signal from the connected sensor from group 16 using an analog-to-digital converter 8, an amplifier-converter of signal level 10, and a switch 11, and the user can mark and / or match the received signal to its logical value.

For example, if an infrared photodetector is connected to a universal contact pair, and the user points the TV remote control at him and presses the “I” button, the user has the opportunity to match the command associated with the “1” button of the remote control and received from the infrared in the equipment profile generator photodetector waveform corresponding to the pressed button. In another example, if a sensor with an interface encoding symbol sequences is connected to a universal contact pair, the user has the option to specify, starting from which symbol in the package, the measured parameter should be read and in what format it should arrive (length in characters, bit depth, conversion method ) Similarly, for a connected actuator from group 17, the equipment profile generator allows the user, through a digital-to-analog converter 7, power switch unit 9, and switch 11, to verify that the parameters for the connected device are correct and, if necessary, calibrate it.

After that, the equipment profile generator transfers the newly created profile to the local storage of equipment profiles, and it, in turn, transfers the newly created equipment profile to the global storage of equipment profiles through communication channels. Since the “smart home” systems installed in different places and belonging to different users have access to the global storage of equipment profiles, the profile of equipment once added to one of the systems automatically becomes available to all other systems. As a result, in a short time of using “smart home” systems in the global repository of equipment profiles, there will be profiles for almost all the sensors and actuators common on the market, and new users of “smart home” systems will not have to manually create these profiles. New equipment will be available for use immediately after connecting to the system and choosing its type, without laborious settings. Separate equipment (for example, connected via the 1-wire protocol) will become available automatically even without selecting its type.

After completing the settings and during the use of the Smart Home system with intelligent adaptive input / output, if a sensor from the sensor group 16 is connected to the universal contact pair 15, the sensor signal is sent to the switch 11. The equipment adapter 4 makes a request to the local profile storage 5 for determining the type of equipment connected to the universal contact pair 15. Since the connected equipment is a sensor, the switch sends the signal received from the sensor to the signal level amplifier-converter 10. The signal amplifier-amplifier, having received from the equipment adapter information about the scaling factor, level restrictions and signal processing methods, amplifies / attenuates or converts signal into a form (voltage, current, etc.), which the analog-to-digital converter is able to perceive 8. The converted signal is sent to an analog-to-digital converter atelier, and then to the equipment adapter, where the signal is compared with its logical value in the framework of the Smart Home system. The further way of using the sensor signal does not differ from those generally accepted in “smart home” systems and presented in the analogue. It can be recorded in the operation log, transferred via communication channels to a remote server, used in checking conditions or in reproducing scenarios of the operation of the Smart Home system.

Similarly, if an actuator from group 17 was connected to a universal contact pair 15, when it became necessary to use it (a command from the control panel, a command from a script, executing a conditional statement, a command from a remote server, or by a signal from one of the other system input interfaces “ smart home ”), the equipment adapter, using the actuator profile obtained from the local storage of equipment profiles, configures the switch so that the universal contact I was connected to a pair of power switching unit 9. The adapter equipment according to the necessity and configuration hardware profile generates a control signal understandable given actuator and corresponding situation. The signal is then sent to a digital-to-analog converter, where it is converted to analog form. Then, using the power switch block, the signal level and power are reduced to a value that can effectively act on the actuator, after which the signal through the switch and the universal contact pair acts on the actuator.

The communication channels can be local Ethernet, RS485 or others, as well as wireless networks of WiFi, ZigBee and others, as well as the global Internet. A remote server can be a computer (workstation) or a stand-alone device that acts as a server and connected to a local network (home, enterprise, etc.) or to the global Internet, on which server software for private or public access to the settings of the Smart Home settings. One of the modern options for a remote server is a "cloud" service, deployed in a distributed cloud storage.

As a microprocessor, you can use a microprocessor control board, for example, on the ARM9 platform, or a general purpose microcontroller, such as Atmegal28, which have built-in random access memory, built-in program flash memory, built-in non-volatile memory, universal programmable input-output ports, built-in multi-channel analog-to-digital and digital-to-analog converters, as well as optionally - UART, Ethernet, USB and other interfaces that may be needed for a specific implementation of the system em. The equipment adapter and the equipment profile generator can be located in the flash memory of the microcontroller, the local storage of equipment profiles can be located in the non-volatile memory of the microcontroller or external memory modules, such as an SD card, connected directly to the microcontroller via UART or SPI interfaces. The power switch block can be a block containing IGBT or MOSFET keys with optical isolation, as well as opto-sims and other relay or solid-state devices for controlling electric current and voltage. The signal level amplifier-converter can consist of controlled operational amplifiers, controlled voltage dividers, filters, galvanic isolation. The switch can be implemented as a group of electromagnetic relays, or as a solid-state version on semiconductor switches. A group of sensors can include both elementary sensors, such as temperature, humidity, light level, presence, direction and wind speed sensors, and complex and intelligent sensors, such as electric energy meters, infrared receivers having their own interaction protocol. The group of actuating devices may include relays, dimmers of lighting, frequency converters of electric drives, infrared emitters, electromagnetic valves of liquids and gases, actuators of air dampers and other types of actuating devices.

The proposed solution is more efficient than the prototype, because, firstly, it has significantly greater versatility and significantly lower cost of building complex smart home systems, and secondly, it provides the opportunity to significantly expand the range and range of smart home systems »Sensors and actuators of various manufacturers and meeting various standards of the input and / or output signal in its form, level and logic of operation without the need to make changes to the control itself device. In addition, the proposed Smart Home system with intelligent adaptive input / output requires less time, knowledge and resource costs for setting up and commissioning.

Information sources:

[1] - RF Patent No. 22010104, IPC G06F 15/16, H01H 83/00, H02H 7/00, publ. 2003

[2] - RF Patent No. 53510, IPC H02H 7/00, G06F 19/00, publ. 2006 year

Claims (1)

The Smart Home system with intelligent adaptive input / output, containing N groups of sensors, N groups of actuators and a control unit consisting of a microprocessor, characterized in that it additionally contains an equipment profile generator that queries existing equipment profiles, generates and transfers generated equipment profiles to the local and global storage of equipment profiles, local storage of equipment profiles, equipment adapter that unifies pairs equipment meters of different standards and different manufacturers without making any changes to the Smart Home system itself, digital-to-analog converter, analog-to-digital converter, global storage of equipment profiles, N input-output modules consisting of a power key unit, signal level amplifier-converter and switch , and the global storage of equipment profiles is made in the form of storage on a remote server.

Images