Volume 4, Issue 3, June 2015, Page: 49-53
Portable Weather System for Measure and Monitoring Temperature, Relative Humidity, and Pressure, Based on Bluetooth Communication
Edgar Manuel Cano Cruz, Department of Computer Science, University of the Istmo, Ixtepec, Mexico
Juan Gabriel Ruiz Ruiz, Department of Computer Science, University of the Istmo, Ixtepec, Mexico
Received: Apr. 21, 2015;       Accepted: May 4, 2015;       Published: May 13, 2015
DOI: 10.11648/j.ajnc.20150403.15      View  3809      Downloads  119
The system also proposes a wireless connectivity by using the Bluetooth communication standard providing of a reliable, portable and a low-cost tool for industry where it is necessary to have an environmental control to carry out critical processes. The weather system consist of an embedded system to the development of multimedia applications based on the PIC32 microcontroller, and development is performed using the SPIES methodology for the construct embedded systems. In this paper the design of a portable system that allows monitoring of four climatic variables (temperature, relative humidity, pressure and altitude). The purpose of the system is to serve as an auxiliary tool to make decisions subsystems for environmental control in different areas.
Embedded System, Bluetooth, Weather System, Sensors
To cite this article
Edgar Manuel Cano Cruz, Juan Gabriel Ruiz Ruiz, Portable Weather System for Measure and Monitoring Temperature, Relative Humidity, and Pressure, Based on Bluetooth Communication, American Journal of Networks and Communications. Vol. 4, No. 3, 2015, pp. 49-53. doi: 10.11648/j.ajnc.20150403.15
Official webpage of humidity and temperature sensors APC (2011). Retrieved by 2014, from http://www.apc.com/.
Official webpage of Arduino firm (2014). Retrieved by 2014, from http://arduino.cc/en/Main/arduinoBoardUno
Hernández, R. Control System of Humidity and Temperature for Greenhouses (2004). Universidad Pedagógica y Tecnológica de Colombia (UPTC).
Mikro Elektronika. Official webpage of Mikro Elektronika firm (2014). Retrieved by 2014, from http://www.mikroe.com/.
OMM. Official webpage of World Meteorological Organization (2014). Retrieved by 2014, from http://www.wmo.int/pages/index_es.html.
Prieto, R. Diagnóstico de las capacidades, fortalezas y necesidades para la observación, monitoreo, pronóstico y prevención del tiempo y el clima ante la variabilidad y el cambio climático en México (2008). INECC.
SEMAR. Official webpage of Mexican Navy Secretariat (2013). Retrieved by August 2014, from http://meteorologia.semar.gob.mx/index.php.
SEMAR. Information of surface automatic weather systems (AWS) in Coatzacoalcos, Veracruz (2013). Retrieved by 2014, from http://meteorologia.semar.gob.mx/datos_emas/coatza.htm.
SENSIRION. Official webpage of SHT11 device (2014). Retrieved by 2014, from http://www.sensirion.com/ en/products/humiditytemperature/ humidity-sensor-sht11/.
SENSIRION. Reference manual of SHT11 sensor (2011).
Shugurensky, C., & Caprano, F. (2011). Automatic Control of Agricultural Irrigation with Capacitive Sensors of Soil Moisture. Applications in Grapevine and Olive. Institute of Automation (INAUT).
SMN. Official web page of Mexican Weather Service (SMN), Mexico (2010). Retrieved by August 2014.
SMN. Weather stations of Mexican Weather Service (2010) (SMN). Retrieved by 2014, from http://smn.cna.gob.mx/emas/catalogoa.html.
Telemetría. Official webpage of Telemetría firm (2014). Retrieved by 2014, from http://www.telemetria.com.mx/ monitoreo-de-datacenter.html
Vargas, H. Monitoring System of Humidity and Temperature in Biological Collections by using Free Software Tools (2011). Instituto Nacional de Biodiversidad.
CMMI for Development (CMMI-DEV v1.2), 2006. Software Engineering Institute, Carnegie Mellon University.
García, I., & Cano, E. Designing and implementing a constructionist approach for improving the teaching–learning process in the embedded systems and wireless communications areas, 2011 Computer Applications in Engineering Education.
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