Difference between revisions of "Sensor Data Acquisition"

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==Overview==
 
==Overview==
Traditionally, environmental sensor data from remote field sites were manually acquired during infrequent site visits. However, with today's technology, these data can now be acquired in real-time. Indeed, there are several methods of automating data acquisition from remote sites, but there is insufficient knowledge among the environmental sensor community about their availability and functionality. Moreover, there are several factors that should be taken into consideration when choosing a remote data acquisition method, including [[#Real-time|how immediately the data are needed]], [[#Bandwidth|bandwidth]], [[#Protocols|hardware and network protocols]], [[#Line-of-sight|line-of-sight]], [[#Power|power consumption]], [[#Security|security]], [[#Reliability and Redunancy|reliability and redundancy]], [[Expertise|expertise]], and [[#Budget|budget]]. Here, we provide an overview of these methods and recommend best practices for their implementation.
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Traditionally, environmental sensor data from remote field sites were manually retrieved during infrequent site visits. However, with today's technology, these data can now be acquired in real-time. Indeed, there are several methods of automating data acquisition from remote sites, but there is insufficient knowledge among the environmental sensor community about their availability and functionality. Moreover, there are several factors that should be taken into consideration when choosing a remote data acquisition method, including [[#Real-time|how immediately the data are needed]], [[#Bandwidth|bandwidth]], [[#Protocols|hardware and network protocols]], [[#Line-of-sight|line-of-sight]], [[#Power|power consumption]], [[#Security|security]], [[#Reliability and Redunancy|reliability and redundancy]], [[Expertise|expertise]], and [[#Budget|budget]]. Here, we provide an overview of these methods and recommend best practices for their implementation.
  
 
==Introduction==
 
==Introduction==
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The classic method of acquiring environmental sensor data from remote field sites involves routine technician site visits, in which s/he connects a laptop to a datalogger, an electronic device that records sensor data over time, and manually downloads data recorded since the last site visit. Once the technician returns to the lab, s/he is then responsible for manually uploading these data to a server for [[Sensor Data Quality|processing]] and [[Sensor Data Archiving|archival]].
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While this is method is generally effective, there are many reasons to automate environmental sensor data acquisition. For instance, if the site is not visited frequently enough, datalogger memory can become full and depending on how the datalogger is programmed, sensor data will either overwrite itself or stop recording. This situation often occurs at remote sites that become periodically inaccessible due to environmental conditions, such as heavy winter snow pack. Second, the burden of responsibility for not only the successful retrieval of the sensor data, but also the subsequent upload to a server for safekeeping, lies solely on the technician. Moreover, with any instrumented site, there is the inherent potential for sensor or power failure. Automated data acquisition systems allow technicians to learn of such issues prior to visiting their site, reducing the potential for data loss. Finally, automated data acquisition methods save hundreds of person hours and vehicle miles that would have been spent manually acquiring data or troubleshooting unanticipated problems.
  
 
===Considerations===
 
===Considerations===

Revision as of 10:11, April 22, 2014

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Overview

Traditionally, environmental sensor data from remote field sites were manually retrieved during infrequent site visits. However, with today's technology, these data can now be acquired in real-time. Indeed, there are several methods of automating data acquisition from remote sites, but there is insufficient knowledge among the environmental sensor community about their availability and functionality. Moreover, there are several factors that should be taken into consideration when choosing a remote data acquisition method, including how immediately the data are needed, bandwidth, hardware and network protocols, line-of-sight, power consumption, security, reliability and redundancy, expertise, and budget. Here, we provide an overview of these methods and recommend best practices for their implementation.

Introduction

The classic method of acquiring environmental sensor data from remote field sites involves routine technician site visits, in which s/he connects a laptop to a datalogger, an electronic device that records sensor data over time, and manually downloads data recorded since the last site visit. Once the technician returns to the lab, s/he is then responsible for manually uploading these data to a server for processing and archival.

While this is method is generally effective, there are many reasons to automate environmental sensor data acquisition. For instance, if the site is not visited frequently enough, datalogger memory can become full and depending on how the datalogger is programmed, sensor data will either overwrite itself or stop recording. This situation often occurs at remote sites that become periodically inaccessible due to environmental conditions, such as heavy winter snow pack. Second, the burden of responsibility for not only the successful retrieval of the sensor data, but also the subsequent upload to a server for safekeeping, lies solely on the technician. Moreover, with any instrumented site, there is the inherent potential for sensor or power failure. Automated data acquisition systems allow technicians to learn of such issues prior to visiting their site, reducing the potential for data loss. Finally, automated data acquisition methods save hundreds of person hours and vehicle miles that would have been spent manually acquiring data or troubleshooting unanticipated problems.

Considerations

Here, we provide an overview of important considerations when choosing a remote data acquisition method.. also see site & platform selection...

Real-time

Bandwidth

can be an important consideration, particularly when high frequency data are being collected. Will cameras be utilized at the site? Where is broadband point of presence (POP) located? Does equipment work with required bandwidth? collection/access interval

Protocols

IP: private vs public networks Serial: Many field instrumentation only comes with serial ports, therefore a Serial-to-Ethernet (e.g. Campbell Scientific NLxxx series) converter is required to interface with transmission instrumentation, which often comes with ethernet port.

Line-of-sight

Evaluation of environment, topography, and vegetation. Can be initially determined using LOS calculators, which use DEM models, but must be ground truthed. Often requires a repeater infrastructure. Choosing repeater locations involves many of the same considerations for choosing site selection. Distance to repeater is a factor.

Power

How important is real-time accessibility? (e.g., what is desired collection frequency?). What are the transmission type power requirements, onsite buffer size. Redundancy is preferred, especially in very remote sites. If power is disrupted, will system resume operations?

Security

Physical Security

see Sensor, Site, and Platform Selection

Network Security

Encryption keys, VPN

Reliability and Redundancy

of transmission mode and of equipment

Expertise

Plug-n-play vs.

Budget

Costs of implementing a data acquisition and transmission method depend on existing infrastructure, initial setup costs including personnel, personnel costs, specifically technician maintenance, and recurring costs, such as monthly recurring costs with cellular transmission.

Methods

There are three main categories of remote data acquisition methods: manual, unidirectional telemetry, and bidirectional telemetry. Each has advantages and disadvantages in terms of infrastructure, cost, reliability, required expertise, and power consumption.

Manual

This method involves scheduled visits to the site by a field technician, who uses a serial-to-computer connection and/or flash memory transfer of environmental sensor data to their laptop or similar device. Upon returning from the field, the technician is responsible for manually uploading these data to a server. This acquisition method is simple and may be the only option when site instrumentation generates large data files. However, this method provides no real-time data access and therefore, no knowledge of instrumentation failures. Moreover, the reliability of this method is completely dependent on the technician.

Unidirectional

Bidirectional

Best Practices

Case Studies

Resources

References