lume XXXIX-B4, 2012 
ETWORKS IN 
400076 Mumbai, 
ment, Agriculture 
form for better decision 
'ver-increasing spread of 
or networks on common 
iltural domain. The Open 
semantic and syntactic 
Server) were selected to 
operable data processing 
vation Service (SOS). An 
he retrieval of crop water 
client has also the ability 
N systems has shown that 
collected sensor data and 
ossible to implement the 
ir specific format (Honda 
. Sudharsan et al., 2012; 
t for users from diverse 
t lineage of collected data 
formats and increases the 
a discovery. Hence, there 
cations and encodings to 
mmon platform to resolve 
y issues (Durbha et al., 
n (OGC) has brought 
| Sensor Web Enablement 
2006; Walter and Nash, 
n through four standard 
rvices such as Sensor 
Planning Service (SPS), 
xification Service (WNS) 
ng sensors and sensor 
| Language (SensorML), 
L) and Observation and 
is, 2012). 
o propose and implement 
ich as Sensor SensorML, 
n of agriculture based 
.. 2012; Tripathy et al., 
ted sensing devices Were 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B4, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
used. The integrated client that has been developed can 
facilitate seamless integration and online visualization of 
sensor observations and measurements for agriculture 
applications. 
2. GEOSENSE 
GeoSense is an Indo-Japan initiative on integrating Geo-ICT 
and WSN for Precision Agriculture. Two sensor systems 
(AgriSens and FieldServer) were implemented. Dynamic real 
to near-real time data was collected, processed, analysed, and 
mined to provide location based services and agricultural 
advisory. 
2.1 AgriSens (AS) 
AS consists of Stargate (base station) communicating to 
various sensor hubs called Motes, which were placed in 
different positions and distributed across the field (SPANN 
Lab, 2011). Stargate plays an important role in receiving the 
data from the motes network and transmitting the data to 
remote server through mobile cellular GPRS / 3G network. 
Each mote has an array of sensors placed at various locations 
on the mote (Figure 1). 
  
    
   
  
   
  
  
  
Temperature sensor 
Humidity sensor 
Leaf Wetness Sensor 
Soil Moisture sensor 
Soil Temperature 
sensor 
  
  
Figure 1. Mote of AgriSens (GeoSense, 2011) 
Different sensors used in AgriSens are Temperature, Humidity, 
and Leaf Wetness. The details of sensors are specified in Table 
| (Neelamegam et al., 2007). 
  
   
   
  
SN | Name Make 
Temperature Sensor | LM61 BIZ 
Humidity Sensor SY-HS-220 
Leaf Wetness | Vantage Pro2 6420 
Sensor 
À Mote wirelessly communicate in Zigbee mode (receiving and 
transmitting) among themselves and transfers the collected 
¥nsor data to the base station (Stargate). The basic 
actions between various sensors of the mote are shown in 
1gure 2. 
  
  
  
  
  
  
  
Table 1. Sensor Details 
437 
  
een ee 
íi Temperature i i Humidity 
; Sensor Ld Sensor 
  
  
          
Recordcr 
ML, temperature 
Mote Data recording sensors and 
activities 
^ NEN Record of 
Record of Record of (eat the data 
timestamp emn 
H ^ 
í yr d X ss | 
i Clock : Leaf Wetness | 
d ; Ci Sensor 
    
Record of 
turoidiby 
     
station 
       
  
        
  
      
  
From base 
station to 
Remote 
Serveron 
Internet 
  
  
  
  
7 
  
  
Figure 2. Sensor process model 
2.2 FieldServer (FS) 
FS is evolved out of many dynamic experiments on 
agriculture/environmental aspects in 90's and currently, 3rd 
generation FieldServers are available. It is a WiFi (long range 
communication) based self-organizing distributed sensing 
device (Figure 3) with 24 bit and 24 channels. The embedded 
board in FS can accommodate the sensors to sense weather, 
agricultural and environmental parameters such as air- 
temperature, humidity, relative humidity, CO», etc. FS 
transfers sensory data directly to the gateway, a central server 
in the field, it is then transmitted further over remote server on 
to the web (FieldServer, 2011). 
  
Fon-- (WiFi) & 3G 
network 
+ Solar Radiation Sensor 
Camera 
- 
FS Processing 
Board & Sensor Unit 
Temperature Sensor 
Humudity Sensor 
   
  
  
  
  
Figure 3. FieldServer installed in field 
(GeoSense, 2011) 
3. SENSOR WEB ENABLEMENT IN GEOSENSE 
Presently, although the GeoSense is based on Open Source 
Consortium (OSC) standards, each sensing system has its own 
data format thus contributing to the diversity of the data 
sources. This brings out semantic and syntactic heterogeneity 
in the sensory database. To facilitate interoperability and data 
discovery there is a need for implementing OGC SWE 
standards. 
3.1 SensorML for GeoSense 
SensorML is a eXtensible Markup Language (XML) 
representation used to represent the different aspects of sensor 
system. It describes details on different aspects like sensor 
system description, process model, process chain, connections, 
system physical layout, etc. (Figure 4) (Botts and Robin, 2007).