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Automated garden system for outdoors
Stupka, Tomáš ; Povalač, Aleš (referee) ; Frýza, Tomáš (advisor)
The aim of this semester work is to design and implement an automated irrigation system for use in a family house based on the Raspberry Pi platform and AVR processors with the possibility of automatic adaptation to outdoor temperature and humidity conditions. The design also includes a web interface using the NodeRED interface for manual control and monitoring of data collected from individual wireless sensor modules
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Low-power wireless sensor node
Pobiecky, Michal ; Koton, Jaroslav (referee) ; Krajsa, Ondřej (advisor)
The main purpose od this thesis is to design wireless sensor node with emphasis on low power consumption. This device is firstly made of microcontroller Atmel ATmega328P and for transferring measured data XBee 802.15.4 or transceiver nRF24L01 is used. Subsequently there is a design with Atmel ATmega256RFR2 with integrated wireless part and Lightweight Mesh protocol. Special attention is given to sleep modes and lowering power consumption. For ATmega328P the measurement of these power modes is done.
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Automated Plant Growing
Švancer, Jan ; Široký, Adam (referee) ; Musil, Martin (advisor)
This thesis combines two current trends - the Internet of Things and Urban Agriculture. It describes technologies for wireless sensors communication in smart homes and hardware for their implementation. Based on these technologies smart hardware for automatic plants growing is implemented and connected to cloud with remote access via iOS mobile application.
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Home automation system
Bajgl, Vojtěch ; Král, Jan (referee) ; Kubíček, Michal (advisor)
This thesis deals with home automation systems. First part of the thesis is focused on analysis of commercially available state-of-the-art systems. The most common ones are compared in terms of their functions, properties, principles of operation and their price. Second part of the thesis describes design and development of custom system for home automation. The aim is to build a cheap alternative to the commercially available systems. The design description starts from schematic design of particular components through PCB design to firmware and software development. The system is based on Raspberry PI 2B microcomputer which controls all the required home electronic equipment via user-friendly web-based interface. Several different ways of use of the system are discussed as well as some useful features of the microcomputer.
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Home weather station based on Raspberry Pi
Špringer, Radek ; Červenka, Vladimír (referee) ; Krajsa, Ondřej (advisor)
The aim of this bachelor thesis is to design and build a home weather station using the platform \raspi{}. The weather station is divided into computing and sensor part. The sensor part of the weather station is implemented through a wireless module, which measures the temperature, pressure, brightness and moisture. The measured values are sent to the weather station computer, where they are processed by \raspi{}. The processed values are then stored in a MySQL database on an external web server. On the web server, the user is shown the actually measured values, graphical waveforms of meteorological data with the option to display the course during the selected day of a year.
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Control and monitoring of climate in groups of terrariums
Pavlišin, Tomáš ; Petyovský, Petr (referee) ; Macho, Tomáš (advisor)
The aim of this master thesis is to propose a system for monitoring and regulating the climate in groups of terrariums using the Raspberry Pi platform and subsequent transparent display through the web server. Each group of terrariums has its own control device that wirelessly communicates with the Raspberry Pi control computer. The measured values are stored in the MySQL database on the control computer. The measured values are graphically displayed on the web page.
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Telemetric wireless tire temperature module
Halgoš, Matúš ; Fiedler, Petr (referee) ; Benešl, Tomáš (advisor)
This work dedicates wireless telemetry, specifically one part, which is the measurement of tire temperature. In the individual chapters, giving the reader the reasons who and under what circumstances can benefit from this information introduces the reader to the ways in which the temperature can be measured, processed and sent. In the following chapters, the reader will be introduced to the selection of components used in the design. And the last part deals with the design of hardware and software of the battery-powered module for measuring the temperature of tires, which is part of the datalogger, which collects vehicle driving data.
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Automated Garden System For Outdoors
Stupka, Tomáš
The aim of this article work is to design and implement an automated irrigation systemfor use in a family house. The proposed system is based on the Raspberry Pi platform and AVRmicrocontroller with the possibility of automatic adaptation to outdoor temperature and humidityconditions. The design also includes a web interface using the NodeRED for manual control andmonitoring of collected data from individual wireless sensor modules.
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Telemetric wireless tire temperature module
Halgoš, Matúš ; Fiedler, Petr (referee) ; Benešl, Tomáš (advisor)
This work dedicates wireless telemetry, specifically one part, which is the measurement of tire temperature. In the individual chapters, giving the reader the reasons who and under what circumstances can benefit from this information introduces the reader to the ways in which the temperature can be measured, processed and sent. In the following chapters, the reader will be introduced to the selection of components used in the design. And the last part deals with the design of hardware and software of the battery-powered module for measuring the temperature of tires, which is part of the datalogger, which collects vehicle driving data.
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Automated garden system for outdoors
Stupka, Tomáš ; Povalač, Aleš (referee) ; Frýza, Tomáš (advisor)
The aim of this semester work is to design and implement an automated irrigation system for use in a family house based on the Raspberry Pi platform and AVR processors with the possibility of automatic adaptation to outdoor temperature and humidity conditions. The design also includes a web interface using the NodeRED interface for manual control and monitoring of data collected from individual wireless sensor modules
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