Real-Time Environmental Monitoring Sensors and Systems

The natural environment is complex and changes continuously at varying paces. Many, like the weather, we notice from day to day. However, patterns and rhythms examined over time give us the bigger picture. These weather statistics become climate and help us build an understanding of the patterns of change over the long term. Real-Time Environmental Monitoring: Sensors and Systems introduces the fundamentals of environmental monitoring, based on electronic sensors, instruments, and systems that allow real-time and long-term data acquisition, data-logging, and telemetry. The book details state-of-the-art technology, using a practical approach, and includes applications to many environmental and ecological systems. In the first part of the book, the author develops a story of how starting with sensors, you can progressively build more complex instruments, leading to entire systems that end with databases and web servers. In the second part, he covers a variety of sensors and systems employed to measure environmental variables in air, water, soils, vegetation canopies, and wildlife observation and tracking. This is an emerging area that is very important to some aspects of environmental assessment and compliance monitoring. Real-time monitoring approaches can facilitate the cost effective collection of data over time and, to some extent, negate the need for sample, collection, handling, and transport to a laboratory, either on-site or off-site. It provides the tools you need to develop, employ, and maintain environmental monitors.

IntroductionFROM SENSORS TO SYSTEMSSensors and Transducers: Basic CircuitsPrinciples of Electrical QuantitiesCircuits: Nodes and LoopsMeasuring Voltages, Currents, and ResistancesSensorsFrom Sensors to TransducersSensor Specifications: StaticResistive SensorsExample: From a Light Sensor to a Light TransducerExample: From Thermistor to Temperature TransducerExample: A Temperature Transducer for Air, Soil, and WaterExample: ThermocouplesSensors and Transducers: Bridge Circuits, Dynamic Specifications, More SensorsIntroductionBalanced Source Voltage DividerOne-Sensor Circuit: Quarter-BridgeTwo-Sensor Circuit: Half-BridgeTwo-Sensor Having Opposite Effect: Half-BridgeFour Sensor Circuit: Full BridgeZero Adjust and Range AdjustSensor SpecificationsElectrochemical SensorsExample: Dynamic Specifications and a Potentiometer-Based Wind DirectionDielectric PropertiesExample: Piezoelectric SensorsExample: Soil TensiometerExercisesSignal Conditioning and Analog-to-Digital ConvertersIntroductionOperational AmplifiersLinearization of the Bridge Circuit OutputCommon-Mode RejectionInstrumentation AmplifierSpectrumNoiseElectric Field and Electrostatic ShieldingIsolationCold-Junction CompensationAnalog-to-Digital ConverterCurrent Loop: 4–20 mAPulse SensorsExercisesData Acquisition SystemsIntroductionDataloggersApplications in Environmental MonitoringAnalog ChannelsReal-Time ClockCommunications with a DataloggerRS-232 StandardSDI-12Conditions and EnclosuresDatalogger Example: CR1000VoltSEVoltDiffBrHalfBrFullPulseCountSupervisory Control and Data AcquisitionExercisesSingle-Board Computers and MicrocontrollersIntroductionComputer Organization and ArchitectureSingle-Board ComputersARM ArchitecturesSBC Based on ARM Processor: ExampleSystem on a ChipSBC Example: Raspberry PiMicrocontrollersMCU ExampleIn-Circuit Serial ProgrammingMCU-Based SBC Example: ArduinoComparing SBCs: TS-7400, Raspberry Pi, Arduino UnoMCUs as DASExample: Arduino ProgrammingExample: Using Flash Memory for Datalogging with ArduinoExample: Using a Datalogger Shield for ArduinoExample MCU-Based SBCExercisesWireless Technologies and TelemetryIntroductionWave ConceptsRadio Wave SpectrumRadio Wave PropagationPropagation ModelsPhase ShiftFresnel ZonesAbsorptionRadio Frequency CablesPower in dBmAntennasFade MarginPolarizationModulation: Digital SignalsMultiplexingSpread SpectrumWi-FiExample: A Low-Cost Wi-Fi RadioExample: Establishing a Wi-Fi Link to Connect a Weather Station to the InternetCellular Phone NetworkArgosExercisesWireless Sensor NetworksIntroductionWSN NodesNetworks: OSI ModelMedia Access ControlMultihop Wireless CommunicationNetwork Protocol for Environmental MonitoringRadio Propagation and WSNExample of Radio Propagation ExperimentsExample: WSN for Soil Moisture in a Hardwood Bottomland ForestWSN: Energy ScavengingExercisesPowerIntroductionPhotovoltaicSolar Radiation and EfficiencySolar Cell ModelFrom Cell to ModuleShading and Bypass DiodeLoad and PowerMaximum Power Point TrackingEfficiency and PerformanceTilting the Panel Atmospheric EffectsSun PathImpact of Temperature on Solar PanelExample: Powering a Remote Monitoring StationExercisesDatabases and Web AccessIntroductionExamples of Raw Data FormatRelational DBsStructural Query LanguageExtensible Markup LanguageBackupWeb ServicesMetadata, Standards, Interoperability, and PreservationExample: Data Collected from Distributed Sensor SystemsExercisesAPPLICATIONS TO ATMOSPHERIC PROCESSES, WATER RESOURCES, TERRESTRIAL ECOSYSTEMS, AND WILDLIFE MONITORINGAtmospheric MonitoringIntroductionEarth’s AtmosphereVertical StructureAtmosphere–Near-Surface Air QualityParticulate MatterStationsOptical DevicesMeasurement Methods Using Samples in Closed PathOptical Absorption SpectroscopyChemiluminscent AnalyzerFluorescenceNondispersive InfraredMeasurement Methods Using Open PathTotal Column MeasurementsAtmosphere–WeatherExample: Measuring UV and TC Ozone Concentration by OAS and DOASHydrology, Hydrodynamics, Water Quality, and Aquatic EcosystemsIntroductionWaterWater Level and DepthWater Velocity and FlowWater Quality ParametersWater Quality SensorsProductivity and RespirationLight as a Function of DepthAutomated Real-Time BiomonitoringTerrestrial EcosystemsIntroductionSoil MoistureSap FlowProductivityNetworksTree Growth: DendrometersLeaf AreaSolar RadiationInfrared ThermometerWildlife MonitoringIntroductionRadio TagsRadio Tags in WaterAcoustic Tags in WaterRadio Frequency Identification and Passive Integrated TransponderPopup Satellite Archival TagsGPS TrackersFish TagsData Storage TagsCamera and VideoProximity SensorsAppendix I: Introduction to RReferences

Miguel F. Acevedo obtained his Ph.D. degree in Biophysics from the University of California, Berkeley. Dr. Acevedo has 38 years of academic experience, the last 20 of these at the University of North Texas.