Geokon 8800-2-2B, 8800-4-1A, 8800-4-1B, 8800-4-2B, 8800-4-2A Instruction Manual

Instruction Manual

No part of this instruction manual may be reproduced, by any means, without the written consent of Geokon, Inc.

Model 8800 series

GeoNet Wireless

The information contained herein is believed to be accurate and reliable. However, Geokon, Inc. assumes no responsibility

for errors, omissions or misinterpretation. The information herein is subject to change without notification.

Copyright © 2014-2018 by Geokon, Inc.

(Doc Rev N, 11/14/2018)

Warranty Statement

Geokon, Inc. warrants its products to be free of defects in materials and workmanship, under
normal use and service for a period of 13 months from date of purchase. If the unit should
malfunction, it must be returned to the factory for evaluation, freight prepaid. Upon examination
by Geokon, if the unit is found to be defective, it will be repaired or replaced at no charge.
However, the WARRANTY is VOID if the unit shows evidence of having been tampered with
or shows evidence of being damaged as a result of excessive corrosion or current, heat, moisture
or vibration, improper specification, misapplication, misuse or other operating conditions outside
of Geokon’s control. Components which wear or which are damaged by misuse are not
warranted. This includes fuses and batteries.

Geokon manufactures scientific instruments whose misuse is potentially dangerous. The
instruments are intended to be installed and used only by qualified personnel. There are no
warranties except as stated herein. There are no other warranties, expressed or implied, including
but not limited to the implied warranties of merchantability and of fitness for a particular
purpose. Geokon, Inc. is not responsible for any damages or losses caused to other equipment,
whether direct, indirect, incidental, special or consequential which the purchaser may experience
as a result of the installation or use of the product. The buyer’s sole remedy for any breach of this
agreement by Geokon, Inc. or any breach of any warranty by Geokon, Inc. shall not exceed the
purchase price paid by the purchaser to Geokon, Inc. for the unit or units, or equipment directly
affected by such breach. Under no circumstances will Geokon reimburse the claimant for loss
incurred in removing and/or reinstalling equipment.

Every precaution for accuracy has been taken in the preparation of manuals and/or software,
however, Geokon, Inc. neither assumes responsibility for any omissions or errors that may
appear nor assumes liability for any damages or losses that result from the use of the products in
accordance with the information contained in the manual or software.

TABLE of CONTENTS

1. INTRODUCTION .................................................................................................................................................. 1

SENSOR NODE ..................................................................................................................................................... 1

1.1

NETWORK SUPERVISOR ...................................................................................................................................... 1

1.2

NETWORK CONSIDERATIONS .............................................................................................................................. 2

1.3

2. NETWORK INSTALLATION.............................................................................................................................. 4

2.1

ITEMS NEEDED .................................................................................................................................................... 4

CHANNEL CONFIGURATION ................................................................................................................................ 4

2.2

CONNECTING SENSORS ....................................................................................................................................... 5

2.3

2.3.1 Cable Gland Models (8800-1-1_) .............................................................................................................. 5

2.3.2 10-pin Bulkhead Models (8800-1-2_) ........................................................................................................ 5

ANTENNA INSTALLATION.................................................................................................................................... 5

2.4

BATTERY INSTALLATION .................................................................................................................................... 6

2.5

ACCESSORIES ...................................................................................................................................................... 7

2.6

DEPLOYMENT MODE ........................................................................................................................................... 7

2.7

STATUS BUTTON FUNCTIONALITY ...................................................................................................................... 8

2.8

2.8.1 Overview .................................................................................................................................................... 8

2.8.2 Supervisor .................................................................................................................................................. 8

2.8.3 Node ........................................................................................................................................................... 9

3. GEONET MULTIPLEXER ..................................................................................................................................11

INSTALLATION ...................................................................................................................................................11

3.1

3.1.1 Mounting the Multiplexer ..........................................................................................................................11

3.1.2 Lightning Protection .................................................................................................................................12

CONNECTING TO THE NODE ...............................................................................................................................12

3.2

CONNECTING SENSORS ......................................................................................................................................12

3.3

3.3.1 10-pin Bulkhead Models (8800-8-2) .........................................................................................................12

3.3.2 Cable Gland Models (8800-8-1 and 8800-8-3) .........................................................................................12

3.3.3 Determining Correct Wiring .....................................................................................................................13

SHARED CHANNELS ...........................................................................................................................................14

3.4

4. GEONET ADDRESSABLE SENSOR NODES ..................................................................................................15

4.1

SENSOR WIRING .................................................................................................................................................15

TROUBLE SHOOTING ..........................................................................................................................................16

4.2

5. ADD ON MODULES FOR SUPERVISOR COMPATIBILITY WITH ETHER NET AND CELLULAR

MODEMS ...................................................................................................................................................................17

INTRODUCTION ..................................................................................................................................................17

5.1

INSTALLATION ...................................................................................................................................................17

5.2

5.2.1 Setting up the 8800-2-4A (Cellular Modem Add-on) ................................................................................17

5.2.2 Setting up the 8800-2-4B (Ethernet Add-on) .............................................................................................18

6. MAINTENANCE ...................................................................................................................................................20

PREVENTING WATER FROM ENTERING THE ENCLOSURES ..................................................................................20

6.1

BATTERY LIFE ...................................................................................................................................................20

6.2

REPLACING BATTERIES ......................................................................................................................................21

6.3

7. TROUBLESHOOTING ........................................................................................................................................22

APPENDIX A. SPECIFICATIONS .........................................................................................................................23

A.1

DEVICE SPECIFICATIONS ...................................................................................................................................23

RADIO SPECIFIC ATIONS .....................................................................................................................................23

A.2

A.2.1 Models Utilizing 2.4 GHz Radios .............................................................................................................23

A.2.2 Models Utilizing 900 MHz Radios ............................................................................................................23

8800-8 MULTIPLEXER SPECIFICATIONS ............................................................................................................24

A.3

APPENDIX B. MODELS ......................................................................................................................................... 25

SUPERVISOR ...................................................................................................................................................... 25

B.1

B.1.1 RS-232 (8800-2-1_ and 8800-4-1_) .......................................................................................................... 25

B.1.2 USB (8800-2-2_ and 8800-4-2_) .............................................................................................................. 25

NODE ................................................................................................................................................................ 25

B.2

B.2.1 Gland Seal (8800-1-1_ and 8800-3-1_).................................................................................................... 25

B.2.2 Bulkhead (8800-1-2_ and 8800-3-2_) ...................................................................................................... 26

MULTIPLEXER ................................................................................................................................................... 26

B.3

B.3.1 Gland Seal (8800-8-1 and 8800-8-3)........................................................................................................ 26

B.3.2 Bulkhead (8800-8-2) ................................................................................................................................. 26

ADDRESSABLE SENSOR NODES ......................................................................................................................... 27

B.4

B.4.1 Gland Seal (8800-5-1_ and 8800-6-1_).................................................................................................... 27

B.4.2 Bulkhead (8800-5-2_ and 8800-6-2_) ...................................................................................................... 27

APPENDIX C. CONNECTOR PINOUTS .............................................................................................................. 28

TRANSDUCER CABLE CONNECTIONS................................................................................................................. 28

C.1

C.1.1 Cable Gland, Models 8800-1-1_ and 8800-3-1_ ...................................................................................... 28

C.1.2 10-Pin Bulkhead, Models 8800-1-2_ and 8800-3-2_ ............................................................................... 28

COMMUNICATION CONNECTIONS ...................................................................................................................... 28

C.2

C.2.1 RS-232, Models 8800-2-1_ and 8800-4-1_ .............................................................................................. 28

C.2.2 USB, Models 8800-2-2_ and 8800-4-2_ ................................................................................................... 28

APPENDIX D. MODBUS ......................................................................................................................................... 29

PROTOCOL ........................................................................................................................................................ 29

D.1

SUPPORTED MODBUS COMMANDS .................................................................................................................... 29

D.2

CONNECTIONS SETTINGS .................................................................................................................................. 29

D.3

SPECIAL CONSIDERATIONS FOR GEONET .......................................................................................................... 29

D.4

SYSTEM INFO TABLE ........................................................................................................................................ 29

D.5

NODE TABLES ................................................................................................................................................... 30

D.6

EXTENDED MEMORY ........................................................................................................................................ 31

D.7

CONVERSIONS ................................................................................................................................................... 33

D.8

D.8.1 Battery Voltage ........................................................................................................................................ 33

D.8.2 Board Temperature .................................................................................................................................. 33

D.8.3 Thermistor ................................................................................................................................................ 33

DATA TYPES ..................................................................................................................................................... 34

D.9

APPENDIX E. SENSEMETRICS MANAGEMENT PLATFORM ..................................................................... 35

E.1

CHANNEL CONFIGURATION ............................................................................................................................... 35

STATUS BUTTON ............................................................................................................................................... 36

E.2

APPENDIX F. FIRMWARE UPGRADE ............................................................................................................... 37

F.1

PROCEDURE ....................................................................................................................................................... 37

TROUBLESHOOTING ........................................................................................................................................... 40

F.2

FIGURES

FIGURE 1 - SINGLE CHANNEL NODE .............................................................................................................................. 1

FIGURE 2 - NETWOR K SUPERVISOR ............................................................................................................................... 1

FIGURE 3 - CLUSTER TREE NETWORK TOPOLOGY ......................................................................................................... 2

FIGURE 4 - WORKING AROUND OBSTRUCTIONS ............................................................................................................ 2

FIGURE 5 - FRESNEL ZONE ............................................................................................................................................. 3

FIGURE 6 - CHANNEL SELECT SWITCH........................................................................................................................... 4

FIGURE 7 - TERMINAL CONNECTIONS ............................................................................................................................ 5

FIGURE 8 - BATTERY SELECT SWITCH ........................................................................................................................... 6

FIGURE 9 - BATTERY DETAIL......................................................................................................................................... 6

FIGURE 10 - INSTALLATION ORDER ............................................................................................................................... 7

FIGURE 11 - BUTTON LOGIC (SUPERVISOR) ................................................................................................................... 9

FIGURE 12 - BUTTON LOGIC (NODE) ............................................................................................................................10

FIGURE 13 - NODE WITH MULTIPLEXER........................................................................................................................11

FIGURE 14 - SAMPLE WIR ING .......................................................................................................................................13

FIGURE 15 - DIP SWITCH SETTINGS .............................................................................................................................14

FIGURE 16 - 6150E ADDRESSABLE MEMS AND ADDRESSABLE SENSOR NODE ...........................................................15

FIGURE 17 - ADDRESSABLE SENSOR NODE WITH 6150E INSTALLED ............................................................................16

FIGURE 18 – NPORT CONFIGURATION ..........................................................................................................................18

FIGURE 19 – UPDATE FIELDS ........................................................................................................................................19

FIGURE 20 – ENTER IP ADDRESS FOLLOWED BY “:4001” .............................................................................................19

FIGURE 21 - EXTERNAL FLASH READ FLOW DIAGRAM ................................................................................................32

FIGURE 22 - EXAMPLE NETWORK CONFIGURATION .....................................................................................................35

FIGURE 23 - CHANNEL SETTING FOR SENSEMETRICS COMPATIBILITY MODE ...............................................................35

FIGURE 24 - BATTERY SELECTOR SWITCH IN OFF POSITION ........................................................................................37

FIGURE 25 - J1 CONNECTOR DETAIL ............................................................................................................................37

FIGURE 26 - UPGRADE CABLE DETAIL .........................................................................................................................38

FIGURE 27 - CHANNEL SELECTOR SWITCH ...................................................................................................................38

FIGURE 28 - UPDATE PROGRESS ...................................................................................................................................39

TABLES

TABLE 1 - CHANNEL SELECTION ................................................................................................................................... 4

TABLE 2 - SENSOR WIRING ............................................................................................................................................ 5

TABLE 3 - LED INDICATOR MEANING ........................................................................................................................... 8

TABLE 4 - STANDARD SINGLE GAGE WIRIN G ...............................................................................................................13

TABLE 5 - ADDRESSABLE SENSOR WIR ING ...................................................................................................................16

TABLE 6 - BATTERY LIFE..............................................................................................................................................20

TABLE 7 - DEVICE SPECIFICATIONS ..............................................................................................................................23

TABLE 8 - 2.4 GHZ MODELS .........................................................................................................................................23

TABLE 9 - 900 MHZ MODELS .......................................................................................................................................23

TABLE 10 - MULTIPLEXER SPECIFICATIONS .................................................................................................................24

TABLE 11 - RS-232 SUPERVISOR MODELS ...................................................................................................................25

TABLE 12 - USB SUPERVISOR MODELS ........................................................................................................................25

TABLE 13 - GLAND SEAL NODE MODELS .....................................................................................................................26

TABLE 14 - 10-PIN BULKHEAD NODE MODELS ............................................................................................................26

TABLE 15 - GLAND SEAL MULTIPLEXER MODELS ........................................................................................................26

TABLE 16 - 10-PIN BULKHEAD MULTIPLEXER MODELS ...............................................................................................26

TABLE 17 - GLAND SEAL ADDRESSABLE SENSOR NODE MODELS ................................................................................27

TABLE 18 - 5-PIN BULKHEAD ADDRESSABLE SENSOR NODE MODELS .........................................................................27

TABLE 19 - TRANSDUCER CABLE CONNECTIONS (GLAND SEAL) .................................................................................28

TABLE 20 - TRANSDUCER CABLE CONNECTIONS (10-PIN BULKHEAD).........................................................................28

TABLE 21 - COMMUNICATION CONNECTIONS (RS-232) ...............................................................................................28

TABLE 22 - COMMUNICATIONS CONNECTIONS (USB) ..................................................................................................28

TABLE 23 - SYSTEM INFO AND SETTINGS .....................................................................................................................30

TABLE 24 - NODE TABLE DETAIL .................................................................................................................................30

TABLE 25 - CHANNEL DETAIL (SINGLE CHANNEL NODE) ............................................................................................31

TABLE 26 - DATA ARRAY DETAILS (EXT MEMORY) ...................................................................................................32

1. INTRODUCTION

Figure 1 - Single Channel Node

Figure 2 - Network Supervisor

GeoNet is a low power, wireless, data acquisition network, designed to efficiently collect data
from many points. GeoNet is especially beneficial in geographically challenging locations where
a wired infrastructure would be expensive, if not impossible. The system consists of a Network
Supervisor, Sensor Nodes, and Agent Software. (For information regarding the installation and
use of Agent Software, please see the appropriate product manual.)

Features:

• Worldwide operation at 2.4 GHz or select countries at 900 MHz

• Up to 100 Nodes per network (Fewer with the use of GeoNet multiplexers, see Section 3.)

• 12 channels available

• Each Node is capable of storing more than one million data arrays

• Operates with alkaline or lithium batteries

1.1 Sensor Node

Sensor Nodes collect battery and temperature data and will read any of
Geokon’s vibrating wire sensors. Each Node can read one sensor by
itself, or up to eight sensors when connected to a GeoNet Multiplexer.

Nodes ship with the following accessories:

• One 2.1 dBi omnidirectional antenna (For other antenna possibilities,
please contact Geokon technical support.)

• Two D cell batteries

• Four desiccant packs

1

1.2 Network Supervisor

The Supervisor controls the network and is the aggregator of all data
collected by the sensor Nodes. While the Supervisor is similar to the
Nodes in that it will read battery and temperature data, it does not
accommodate a vibrating wire sensor. Data stored by the Supervisor
may be collected by using Agent software or any other Modbus
master. (For information regarding the use of Modbus with GeoNet
hardware please see Appendix D.)

Supervisors ship with the following accessories:

• Two D cell batteries

• Set of two screwdrivers, one Phillips Head and one Flat Head

• Four desiccant packs

• One firmware upgrade cable

• One RS-232 or USB communications cable (depending on the

model purchased)

• One 2.1 dBi omnidirectional antenna (For other antenna
possibilities, please contact Geokon technical support.)

2

1.3 Network Considerations

GeoNet uses network technology that is self-configuring and self-healing. Data from the Nodes
is either sent directly to the Supervisor, or it arrives via communication between the Nodes. This
effectively creates a cluster tree topology. Figure 3 illustrates this concept.

Figure 3 - Cluster Tree Network Topology

Each transmission from Node to Supervisor or Node to Node is considered one “hop”. Examples
of hops are shown in Figure 3 and Figure 4. Up to four hops can be made between a Node and
the Supervisor. With the ability to hop comes the ability for the Supervisor to communicate with
Nodes that have not established direct radio communication. Figure 4 shows how GeoNet
devices can operate around buildings or other barriers using hops.

Figure 4 - Working Around Obstructions

When using GeoNet it is important to take into consideration the radio environment, and to
understand the effect that obstructions have on radio signals. Obstructions between two antennas
can cause reflections of the transmitted signal. When these reflections arrive at the receiving
antenna, they may be in or out of phase with the signal that took a straight-line path. This
reflected signal may act as constructive or destructive interference with the received signal. For
optimum performance, Geokon recommends creating as much vertical space as possible between
the straight-line path and obstacles, including the ground. Figure 5 illustrates what is known as
the Fresnel zone.

3

Figure 5 - Fresnel Zone

If GeoNet is deployed to a site and communication cannot be established, it may be necessary to
elevate the devices, or to move them to a location where a radio link can be established. This
may require extending the readout cable of the attached sensors.

4

Modbus

Channel

1 2 3

4

1

OFF

OFF

OFF

OFF

2

ON

OFF

OFF

OFF

3

OFF

ON

OFF

OFF

4

ON

ON

OFF

OFF

5

OFF

OFF

ON

OFF

6

ON

OFF

ON

OFF

7

OFF

ON

ON

OFF

8

ON

ON

ON

OFF

9

OFF

OFF

OFF

ON

10

ON

OFF

OFF

ON

11

OFF

ON

OFF

ON

12

ON

ON

OFF

ON

13*

OFF

OFF

ON

ON

*

Appendix E for more information.

Figure 6 - Channel Select Switch

Table 1 - Channel Selection

2. NETWORK INSTALLATION

2.1 Items Needed

To install a network, begin with the Supervisor and at least one Node that is within radio range
of the Supervisor.

2.2 Channel Configuration

Channels allow multiple networks to coexist in the same area. All devices are set to
communicate on channel one from the factory and do not need to be altered if operating a single
network in a given area. However, if multiple networks are within radio of one another then the
devices of each network must be set to different channels.

To set the channel on a Node or Supervisor:

1) Open the device by unscrewing the four captive screws on the front of the enclosure. Make
sure that no dirt, water or other contaminants are allowed to enter the enclosure.

2) Set the channel select dipswitch (shown in Figure 6) to any of the 12 valid positions listed in
Table 1.

3) Devices will only communicate with others that have been set to the same channel.

To prevent erratic behavior, there can be only one Supervisor on a particular channel. A
Supervisor with the same channel setting cannot be within radio range of any of the units of
another network.

Address

and

Sensemetrics Thread compatibility

mode, not for use with supervisor. See

2.3 Connecting Sensors

Position

Color

Description

VW+

RED

Vibrating Wire +

VW-

BLACK

Vibrating Wire -

TH+

WHITE

Thermistor +

TH-

GREEN

Thermistor -

Figure 7 - Terminal Connections

A sensor may be attached to a Node before or after the Node has been powered on.

2.3.1 Cable Gland Models (8800-1-1_)

To wire a sensor on models featuring a cable gland:

1) Open the device by unscrewing the four captive screws on the front of the enclosure.

Make sure that no dirt, water or other contaminants are allowed to enter the
enclosure.

2) Loosen the nut on the cable fitting and remove the white plastic dowel.

3) Thread the transducer cable through the cable fitting.

4) Wire each conductor of the cable into the correct position in the terminal block by
pressing down on the corresponding orange tab at the back, inserting the conductor,
and then releasing the orange tab. (Refer to Figure 7 and Table 2 for sensor wiring
information.)

5

SHLD BARE

Table 2 - Sensor Wiring

Analog Ground

(shields)

5) Tighten the nut on the cable fitting so that it securely grips the cable. This must be
done to ensure that water does not enter the enclosure. (Beware of
overtightening, which may damage the plastic threads.)

2.3.2 10-pin Bulkhead Models (8800-1-2_)

Sensors are attached to the Node with a 10-pin Bulkhead connector. Align the grooves on
the sensor connector (male), with the connector on the unit (female). Push the connector
into place and then twist the outer ring of the male connector until it locks.

2.4 Antenna Installation

Remove the rubber cap from the antenna mount. Position the antenna on the mount and then
rotate the antenna in a clockwise direction until tightened.

6

2.5 Battery Installation

Install the D cells in the Supervisor first, followed by the Nodes.

Install the batteries as follows:

1) Open the device by unscrewing the four captive screws on the front of the enclosure. Make
sure that no dirt, water or other contaminants are allowed to enter the enclosure.

2) Prior to installing the D cells, ensure that the battery select switch is set to the “OFF” position
(Figure 8). (For units manufactured prior to June 2017, move the battery select switch to the

OPPOSITE setting of the type of battery that will be installed.)

Figure 8 - Battery Select Switch

3) Install the batteries by aligning the positive (+) side of the D cells with the left side of the
battery holder. Push the batteries straight down into the holder.

Figure 9 - Battery Detail

4) Move the battery select switch to either the “Alkaline” or “Lithium” position depending on
the type of battery being used.

5) An LED will flash on the right side of the box indicating the unit has power.

2.6 Accessories

After the batteries have been installed:

1) Remove the desiccant packs from the plastic seal top bag they were shipped in and place
them inside the enclosure.

2) Reinstall the cover. Ensure that the rubber gasket clean and properly seated in the groove on
the underside of the cover. Tighten the screws a little at a time, working in a diagonal pattern.
Make sure the cover seals tightly and evenly.

3) Mount the device. The built-in mounting plate is designed to be used with U-Bolts, hose
clamps, screws, bolts, etc. Devices should be mounted with the antenna pointing up. (It is not
necessary to point the Node antennas in the direction of the supervisor, and vice versa.)

2.7 Deployment Mode

There are two modes of operation: deployment mode and normal mode. The Supervisor and

Nodes all enter deployment mode upon power up. Do not press the status button at this time.

(For information on the function of the status button, see Section 2.8)

With the Supervisor and Nodes both in deployment mode they will find each other in less than
three minutes (radio circumstances permitting). Once the network has been established, the
Supervisor’s red LED will flash simultaneously with the green LEDs on the Nodes. If the correct
lights do not illuminate, or if the unit has exited deployment mode because the status button has
been pressed, press the status button on the Supervisor again to restart deployment mode.

While in deployment mode, Nodes may be added by simply turning them on within radio range.
Any number of Nodes may be configured at one time; they do not need to be done
simultaneously. When adding Nodes, start with those closest to the Supervisor. It is desirable to
place the Supervisor in the center of the distribution of Nodes when possible (see Figure 10);
doing so will reduce hops, thereby reducing battery consumption.

7

Figure 10 - Installation Order

8

LEDs

Supervisor

Nodes

Time set, Nodes present

Radio signal > 30%

The default time a network will remain in deployment mode is one hour. When a new Node joins
the network the timer will reset, extending the deployment period for another hour. If more time
is needed while deploying Nodes, the default deployment timeout may be changed using Agent
software.

After 10 minutes, the LEDs on the Nodes will stop indicating their status in order to conserve
batteries. Pressing the status button on a Node will reactivate the LEDs for another 10 minutes.

Nodes may be moved to their install locations while the green LED is flashing. Observe the
LEDs while moving the Nodes to ensure a good communication path is maintained.

The network will not begin collecting data until the network time has been set. This may be
accomplished by using the Agent software (or other Modbus master). The default scan interval
for data collection is 10 minutes.

If isolated from the rest of the network, a Node will continue to sample and store data. When
communication is reestablished, it will “catch up” by sending all of the collected data to the
Supervisor.

2.8 Status Button Functionality

2.8.1 Overview

All GeoNet devices have red and green LED indicators to display their status. There is a
reference key printed on the side of each unit, below the LEDs. When the status button is
pressed, the appropriate LED indicators will briefly illuminate. Table 3 shows the
meaning of the various LED indications. (When used in a Sensemetrics network, see
Appendix E for the meaning of the LED indications.)

2.8.2 Supervisor

If the green LED on the Supervisor flashes when the status button is pressed, this
indicates that the network is entering deployment mode. In order to provide timely
feedback to the user, the network parameters will be changed to a 10-second radio
interval.

If the red LED flashes when the status button is pressed, the Supervisor is exiting
deployment mode and will resume normal operation.

Network time not set No radio signal

Table 3 - LED Indicator Meaning

No Nodes present Radio signal < 30%

Changes initiated by the status button will be made on the following radio cycle. This
could take up to three minutes when switching from normal mode to deployment mode,
as changes to the radio settings can only occur when all the radios in the network are
awake.

If the user presses the status button multiple times, the mode of operation will be
whatever is indicated by the final LED flash.

9

2.8.3 Node

If the green LED flashes on a Node when the status button is pressed, it will begin
indicating the status of the radio signal by flashing the LEDs during radio activity. If the
Node has not yet joined the network, it will also change its radio interval to
approximately one second.

If the red LED flashes when the status button is pressed, radio status indicating has been
disabled; no lights will flash thereafter.

Figure 11 - Button Logic (Supervisor)

10

Figure 12 - Button Logic (Node)

11

3. GEONET MULTIPLEXER

The GeoNet Multiplexer expands the number of vibrating wire sensors a Node can read from one
to eight. Channel switching is controlled by the Node and is accomplished by solid-state
(nonmechanical) circuitry.

Each Node with a Multiplexer attached uses the equivalent data of four single nodes. Since the
maximum number of Nodes per Network is 100, the maximum amount of Nodes with a
Multiplexer attached that may be connected to a single network is 25.

The Multiplexer is protected from environmental contaminants by a rugged, NEMA 4X
enclosure, constructed from fiberglass reinforced polyester. It is also shielded from harmful radio
frequencies and electromagnetic interference by a conductive gasket and internal RFI/EMI
coating. An Earth Ground terminal is provided on the exterior of the enclosure to protect against
lightning and other large, transient voltages.

Multiplexers ship with the following accessories:

• Four desiccant packs

• Two lithium D cells (These D cells must be installed in the Node to which the Multiplexer

will be attached.)

3.1 Installation

3.1.1 Mounting the Multiplexer

The Multiplexer is typically mounted in such a manner that the cable entries are facing
downward (as shown in Figure 13 above). Attach the Multiplexer to the mounting surface
by utilizing the Multiplexer’s mounting plate. The mounting plate is designed to be used
with hardware such as U-Bolts, hose clamps, bolts, screws, etc. (Mounting hardware is
not included.)

Figure 13 - Node with Multiplexer

12

3.1.2 Lightning Protection

Each VW (Vibrating Wire) channel is protected by a 230V gas discharge tube, followed
by a high-speed protector and a transient voltage suppression diode. Each TH
(Thermistor) channel is protected by a 230V gas discharge tube, followed by an inductor
(lower resistance than high-speed protectors) and a transient voltage suppression diode.
(See Section A.3 for complete specifications).

In order for these components to divert energy from a lightning strike safely to ground, a
solid electrical connection to earth ground needs to be made. A copper grounding rod, (at
least six feet in length,) should be driven into the soil to a minimum depth of three feet, as
close to the Multiplexer as possible. Alternatively, any other suitable attachment to earth
ground may be utilized. Connect the grounding rod to the copper grounding lug on the
exterior of the Multiplexer with a large gauge wire (12 AWG or larger). This will provide
a suitable path from the Multiplexer to ground in the event of a lightning strike.

3.2 Connecting to the Node

A Multiplexer can be added to a Node at any time; it will be detected and utilized automatically.

Install the lithium D cells into the Node that the Multiplexer will be connected to by following
the instructions in Section 2.5. Connect the Node to the Multiplexer by using a model 8032-5,
10-pin to 10-pin patch cord (sold separately). Align the grooves of the connector on the cable
(male), with the connector on the unit (female). Push the connector into place until seated and
then twist the outer ring of the male connector until it locks into place.

3.3 Connecting Sensors

3.3.1 10-pin Bulkhead Models (8800-8-2)

Sensors are attached to the Multiplexer with 10-pin Bulkhead connectors. Align the
grooves on the sensor connector (male), with the connector on the unit (female). Push the
connector into place and then twist the outer ring of the male connector until it locks.

3.3.2 Cable Gland Models (8800-8-1 and 8800-8-3)

1) Open the Multiplexer by loosening the four captive screws on the front of the
enclosure and removing the lid. Make sure that no dirt, water, or other
contaminants are allowed to enter the enclosure.

2) Loosen cable gland nuts and remove the white plastic dowels. To prevent
contaminants from entering the enclosure, dowels should be left inside cable fittings
that will not be used.

3) Thread the transducer cables through the cable fittings. (For simplest cable
management inside the enclosure, transducer cables should be wired sequentially,
from left to right, top to bottom.)

13

Position

Color

Description

VW+

RED

Vibrating Wire +

VW-

BLACK

Vibrating Wire -

TH+

WHITE

Thermistor +

TH-

GREEN

Thermistor -

SHLD

BARE

Analog Ground (shields)

4) Insert the conductors of each cable into the terminal blocks of the multiplexer by
pressing down on the orange tab at the back of the terminal block, inserting the
conductor, and then releasing the orange tab. See Section 3.3.3 for information on
determining the correct wiring.

5) Tighten the nuts on the cable fittings. This must be done to ensure that water does

not enter the enclosure. Avoid overtightening as this may damage the plastic
threads.

6) Reinstall the cover. Ensure that the rubber gasket is properly seated in the groove on
the underside of the cover. Tighten the screws a little at a time, working in a diagonal
pattern; this ensures that the cover seals correctly.

3.3.3 Determining Correct Wiring

Geokon instruments with a single vibrating wire gage should be wired according to Table

4. (As shown on channels six, seven, and eight in Figure 14.)

Table 4 - Standard Single Gage Wiring

To determine the correct wiring for Geokon instruments with multiple vibrating wire
gages, refer to the wiring chart(s) in the manual provided with the instrument. These
types of instruments will require the use of more than one channel in the Multiplexer. For
example, a five transducer Borehole Extensometer has been wired into channels one, two,
three, four, and five in Figure 14. For instruments that have multiple gages sharing a
single conductor, refer to Section 3.4, “Shared Channels”.

Figure 14 - Sample Wiring

14

3.4 Shared Channels

Some Geokon instruments utilize multiple gages that share a single conductor for negative
polarity. During normal operation, each channel of the Multiplexer consists of four signals,
which are all switched together: VW+, VW-, TH+, and TH-. However, the Multiplexer can be
configured to switch the VW- signal separately from the rest, allowing for configurations where
multiple gages share one common VW- signal. This shared conductor may be connected to the
VW- on any of the channels to which the various gages have been wired.

Switching of the VW- signal is controlled by an eight-position DIP switch located on the left side
the circuit board. This DIP switch tells the Multiplexer which channels are sharing a common
VW- signal. Use the table located on the top left corner of the circuit board (reproduced in Figure

15) to determine which of the eight switches to move to the on position based upon which
channels are sharing a common VW- signal.

For example: If the VW+ conductors of a four gage load cell were wired into channels four, five,
six, and seven, then the common conductor for these gages may be wired into the VW- of any of
those four channels. Consequently, switches four, five, and six on the eight-position DIP switch
would be moved to the ON position.

Figure 15 - DIP Switch Settings

4. GEONET ADDRESSABLE SENSOR NODES

Model 8800-5 and 8800-6 GeoNet Addressable Sensor Nodes are used to communicate with
6150E Addressable MEMS strings (Figure 16).

15

Figure 16 - 6150E Addressable MEMS and Addressable Sensor Node

Addressable Sensor Nodes function in the same manner as other Nodes, and can be installed
using the previous sections in the manual. Because the Node powers the MEMS sensors lithium
batteries are required; therefore, the power switch is on/off only and does not have the option
of selecting alkaline or lithium.

4.1 Sensor Wiring

For sensors that have a 5-pin bulkhead connector attached, align the grooves on the sensor
connector (male), with the connector on the Node (female). Push the connector into place and
then twist the outer ring of the male connector until it locks. For sensors with bare leads, wire the
6150E into the Node per Table 5 and Figure 17 on the following page.

Once the string has been correctly wired into the Node and the unit has been powered on, no
other setup is required with the hardware. The remaining configuration is completed using the
Agent software program. Refer to the Agent instruction manual for more information.

16

Node Connection

Conductor Color

Description

485+

White

Communication RS-485+

485-

Green

Communication RS-485-

12V

Red

12 volt power to the string

GND

Black

Ground

SHLD

Bare

Analog Ground (shields)

Table 5 - Addressable Sensor Wiring

Figure 17 - Addressable Sensor Node with 6150E Installed

4.2 Trouble Shooting

Symptom: Node does not have power

 Check the fuse located to the left of the batteries; replace if necessary.
 Make sure the 12V and GND (red and black) conductors of the 6150E are not shorted.
 Ensure that the polarity of the batteries matches the diagram on the battery holder.
 Check for secure connection between the battery terminals and holder. If a gap exists

between the holder and the battery terminals, remove the batteries and bend the sides of the
holder inward, then reinstall the batteries.

17

5. ADD ON MODULES FOR SUPERVISOR COMPATIBILITY WITH ETHER NET AND CELLULAR MODEMS

5.1 Introduction

Model 8800-2-4A (cellular modem compatibility) and Model 8800-2-4B (Ethernet
compatibility) are add-on modules for the Network Supervisor to allow the end user to easily add
remote communications and data download.

Each module comprises a weather proof, 305 x 254 x 152 mm (12" x 10" x 6") enclosure, a 7Ah
battery, charger, and the necessary cables to interface with an RS232 equipped GeoNet
Supervisor.

When an add-on module is paired with a Network Supervisor, the Supervisor is powered by the
rechargeable battery inside the module. The charge level of the battery can be monitored using
the Agent software program.

5.2 Installation

Both modules are shipped with the battery unplugged and the fuse distribution board switch in
the off position. To deploy the modules, the battery should be plugged into the fuse distribution
board and the switch placed in the ON position. The provided black 10-Pin to 10-Pin connecting
cable is used to connect the module to the Supervisor.

D-cell batteries should still be installed in the supervisor, and the battery switch moved to the
appropriate battery chemistry, so that in the event the module battery level drops, the
communication between the Supervisor and the Nodes will not be interrupted.

5.2.1 Setting up the 8800-2-4A (Cellular Modem Add-on)

The 8800-2-4A requires a configured modem with a static IP address. To install the
modem, complete the following:

1) Place the modem into the modem bracket and secure it using the Velcro strap.

2) Plug the 9-Pin D-sub connector into the RS232 port of the modem.

3) Connect the modem power cable to one of the open load connections on the fuse

distribution board.

4) Connect the coaxial cable to the cellular modem antenna bulkhead

5) Attached the antenna to the bulkhead on the outside of the module.

18

5.2.2 Setting up the 8800-2-4B (Ethernet Add-on)

The MOXA 5110A will be setup by Geokon to communicate with a GeoNet Network
Supervisor, however, the end user will need to finish the setup so that it works with their
network. Configure an IP address by following the instructions below. (Note: The

following steps should only be performed by your network administrator. Nport
administrator (on cd) should be installed and used to configure the required IP
changes.)

1) Connect a computer to the MOXA 5110A via the Ethernet Port.

2) Open NPort Administrator and click “Search”. (By default, the MOXA 5110A IP
Address “192.168.127.254” will be displayed.)

3) Double click on the IP Address under the configuration window.

4) In the configuration window, click on the Network tab.

5) Check the boxes next to “Modify IP address” and “Modify Netmask”, see Figure 18.

Figure 18 – Nport Configuration

19

6) Update the “IP Address”, “Netmask”, “Gateway”, and “DNS Server 1” fields to
match your network. (Note: Do not make any other changes to the settings as it may

affect proper communications to the GeoNet Network Supervisor.)

Figure 19 – Update Fields

7) Click OK.

8) Restart your MOXA Converter.

9) Connect the add on Module to the GeoNet supervisor.

10) Enter the new IP address followed by “:4001” as the “Network Address” in the Agent
Software program.

Figure 20 – Enter IP Address followed by “:4001”

20

Battery Life Estimates

Alkaline

Lithium

Readings

Transmitted

Radio

Cycles

Scan Rates

(minutes)

12

208

583

20

347

972

30

521

1458

60

1042

2915

6. MAINTENANCE

All GeoNet devices are designed to operate in field environments with minimal upkeep;
nevertheless, there are some basic maintenance procedures that should be followed to ensure
maximum reliability and functionality.

6.1 Preventing Water from Entering the Enclosures

GeoNet devices are designed to be splash proof and rain proof, but are not submersible. Devices
are sealed by a gasket, which will prevent water entry, so long as the screws that hold the lid in
place are properly tightened and the gasket inside the lid is properly aligned. It is also very
important to make sure that all the cable fittings are securely tightened. Models that feature a 10­pin connector are equipped with a watertight cap, which must be installed when the connector is
not in use.

Despite all these precautions, the Nodes may encounter leakage along the cable if the cable is
cut, or if the unit is installed in an especially humid environment. In this type of environment, it
is recommended that the internal desiccant packs be replaced at the necessary intervals in order
to prevent condensation from corroding or shorting out the internal electronics.

6.2 Battery Life

Estimating the life of batteries in a system with as many factors, the GeoNet wireless network is
difficult. Battery life is affected by temperature extremes, the radio environment (as related to
retries), and the physical configuration of the Nodes. Nodes that are the only communication link
between other Nodes and the Supervisor will have a shorter battery life than those that have no
routing responsibility.

Table 6 is a conservative estimate of battery life based on the number of readings collected and
sent to the Supervisor. At a one-hour scan rate or higher, with only one hop, over 1,000 days of
battery life can be expected. If greater battery life is needed, a 12-volt nominal input is available.
Contact Geokon technical support for help utilizing this feature.

25,000 70,000

500,000 1,400,000

Days Days

Table 6 - Battery Life

21

6.3 Replacing Batteries

Batteries should be replaced when the measured voltage of the D cells drops below 2.0 VDC or
11 volt for an external 12-volt battery. Units will cease operation at ~2.0 volts. When this occurs,
a new set of batteries must be installed before the unit becomes operational again. (Refer to
Section 2.5 for battery installation instructions.) In order for a Node to resume normal operation
after replacing the batteries, it needs to synchronize with the network and acquire the network
time.

All data is retained in nonvolatile flash memory. Data will not be lost even if the batteries are
removed for an extended period (e.g., years).

Lithium batteries are required for use with Multiplexers. A Multiplexer adds seven channels to a
Node; therefore, it takes more power to transmit the data to the Supervisor. A Node with a
Multiplexer transmits four times as much data as a single channel Node.

22

7. TROUBLESHOOTING

Listed below are a few commonly experienced problems and remedial action. Contact the factory
should a problem arise not explained herein, or if additional information is needed.

Symptom: Unit will not respond to communications

 Wrong connection type, or incorrect port specified in Agent software.
 The internal batteries of the Supervisor may be dead. Replace the batteries.

Symptom: Vibrating wire gage measurement reads -999999.0

 Using an ohmmeter, check connections to the vibrating wire gage leads. Resistance should

be between 90 and 180 ohms (Pins A and B on the 10-pin connector. See Appendix C for
complete pin-out.) Remember to add the cable resistance at approximately 14.7Ω per 1000
ft. or 48.5Ω per km at 20 °C. Multiply this factor by two to account for both directions. If
the resistance is very high or infinite (megohms), the cable is probably broken or cut. If the
resistance is very low (<20Ω), the gage conductors may be shorted.

 Check for a faulty or misconnected gage.

Symptom: Vibrating wire gage reading is unstable

 Is there a source of electrical noise nearby? Likely candidates are generators, motors, arc

welding equipment, high voltage lines, etc. If possible, move the transducer cable away
from power lines and electrical equipment.

Symptom: Thermistor measurement shows -273.15 degrees Celsius

 This indicates an open circuit to thermistor leads. Check connections from the Node or

Multiplexer to the thermistor leads. If okay, check thermistor with an ohmmeter.
APPENDIX D.8.3 details the resistance versus temperature relationship. It should read
between 10K ohms and 2.4K ohms (0 to +30 °C). If the thermistor is functioning correctly,
consult the factory to schedule the unit for repair.

Symptom: Node has weak communication

If the signal is consistently weak (indicated by red and green LEDs illuminated at the same time)
but not intermittently red, proceed with the installation. If the signal is frequently lost (red flash)
it will be necessary to improve it. Try to get the Node as high as possible, with plenty of clear
space around the antenna. Extending the sensor cable may enable moving the Node to a better
location. If the signal does not improve, a higher gain directional antenna may be necessary.
Contact Geokon for help.

Symptom: Node will not synchronize with network

If the red status light on a Node is flashing at 10-second intervals, it means the Node was once
connected to a network, but the network is not present now, or the Supervisor has been reset,
resulting in an equal, but not overlapping radio cycle. Be sure that the network is functioning in
deployment mode, (red light flashing every 10 seconds on the Supervisor,) then remove and
replace the batteries in the Node. The Node will now look for the changed network.

APPENDIX A. SPECIFICATIONS

8800-1 (Node)

8800-2 (Supervisor)

Units

Measurement Accuracy

±0.1% F.S. (400-5000 Hz)

NA

Hz

Data Memory

32

MB

Storage Capacity

1.44E+06

1.06E+06

Arrays

Temperature Range

-40 to +85

°C

Thermistor Accuracy

2% F.S.

Thermistor Resolution

0.1

Communication Type

NA

USB/RS-232

Communication

NA

115k,8-N-1

Communication Protocol

NA

Modbus RTU

Power Supply

D Cell Alkaline or Lithium (2x)

Scan Interval

10-1440

Minutes

L x W x H

122 x 120 x 91 mm (4.8" x 4.7" x 3.6")

mm (in.)

Network

North American

International

Units

Topology

Mesh/Cluster Tree

Radio Technology

IEEE 802.15.4 DSSS

Radio Frequency, ISM Band

2.4

GHz

Channels

12

Range (Indoor, Urban)

90

60

M

Receiver Sensitivity

-100

dBm

Network Throughput (1,2,4 hops)

78, 50, 22

kbps

Antenna (half-wave dipole)

2.1

dBm

Description

Value

Units

Topology

Mesh/Cluster Tree

Radio Technology

IEEE 802.15.4 FHSS

Radio Frequency, ISM Band

900-928

MHz

Channels

12

Range (Indoor, Urban)

305

M

Range (Outdoor, line-of-sight)

6500

M

Transmit Power (N.A. / International)

250

mW

Receiver Sensitivity

-101

dBm

Network Throughput (1,2,4 hops)

78, 50, 22

kbps

Antenna (half-wave dipole)

2.1

dBm

A.1 Device Specifications

Table 7 - Device Specifications

A.2 Radio Specifications

A.2.1 Models Utilizing 2.4 GHz Radios

23

NA °C

Range (Outdoor, line-of-sight)

Transmit Power

Table 8 - 2.4 GHz Models

1600 750 M

63 10 mW

A.2.2 Models Utilizing 900 MHz Radios

Table 9 - 900 MHz Models

24

Power Requirements:

2.8-3.6 VDC (regulated 3.3V provided by GeoNet Node)

Quiescent Current:

50uA

Active Current:

1.5mA typical, 10mA MAX

Operating Temperature:

-30 ° to +85 °C

MUX Cable Length:

10 ft. (max)

Dimensions:

279.4 mm x 177.8 mm x 88.9 mm (11" x 7" x 3.5")

Type:

CMOS, Solid-state

Power:

4µA (max combined current for all switches)

On Resistance:

5Ω (max)

Switching Time:

14ns

DC Breakdown Voltage:

230V

Surge Life:

100 operations (10/1000µs @ 200A)

Max Surge Current:

8 operations (8/20µs @ 5kA)

Trip Current:

300mA

Resistance:

7.6Ω (typical)

Response Time:

1µs (max)

Reverse Standoff Voltage:

3.3V

Peak Pulse:

260W, 20A (8/20µs)

Rated Current:

650mA

Inductance:

10µA

Resistance:

250mΩ

A.3 8800-8 Multiplexer Specifications

GENERAL

ANALOG SWITCH

GAS DISCHARGE TUBE

HIGH-SPEED PROTECTOR

TRANSIENT VOLTAGE SUPPRESSOR

INDUCTOR

Table 10 - Multiplexer Specifications

25

Model #

PC Connection

Frequency

Region

8800-2-1A

RS-232

2.4 GHz

North America

8800-2-1B

RS-232

2.4 GHz

International

8800-4-1A

RS-232

900 MHz

North America

8800-4-1B

RS-232

900 MHz

Brazil

8800-4-1C

RS-232

900 MHz

Australia

Model #

PC Connection

Frequency

Region

8800-2-2A

USB

2.4 GHz

North America

8800-2-2B

USB

2.4 GHz

International

8800-4-2A

USB

900 MHz

North America

8800-4-2B

USB

900 MHz

Brazil

8800-4-2C

USB

900 MHz

Australia

APPENDIX B. MODELS

Model types are distinguished by their various physical connections, as well as their radio output
power. Radio output options include North America, Brazil, Australia, and international.

B.1 Supervisor

Supervisor model types are distinguished by radio output, as well as their physical connection to
a PC.

B.1.1 RS-232 (8800-2-1_ and 8800-4-1_)

Connects to a PC running the Agent program or other Modbus RTU master via an RS­232 cable.

Table 11 - RS-232 Supervisor Models

B.1.2 USB (8800-2-2_ and 8800-4-2_)

Connects to a PC running the Agent program or other Modbus RTU master via a USB
cable. The Supervisor will be powered from the USB bus when plugged into the PC.

Table 12 - USB Supervisor Models

B.2 Node

Node model types are distinguished by radio output, as well as their sensor connection options.

B.2.1 Gland Seal (8800-1-1_ and 8800-3-1_)

For use with sensors cables with stripped and tinned ends. The sensor cable passes
through an external cable gland and is wired into the terminal block according to Section

2.3.1.

26

Model #

Cable Connection

Frequency

Region

8800-1-1A

Cable Gland

2.4 GHz

North America

8800-1-1B

Cable Gland

2.4 GHz

International

8800-3-1A

Cable Gland

900 MHz

North America

8800-3-1B

Cable Gland

900 MHz

Brazil

8800-3-1C

Cable Gland

900 MHz

Australia

Model #

Cable Connection

Frequency

Region

8800-1-2A

10-Pin Bulkhead

2.4 GHz

North America

8800-1-2B

10-Pin Bulkhead

2.4 GHz

International

8800-3-2A

10-Pin Bulkhead

900 MHz

North America

8800-3-2B

10-Pin Bulkhead

900 MHz

Brazil

8800-3-2C

10-Pin Bulkhead

900 MHz

Australia

Cable Glands

Size

Qty

8800-8-1

Cable Gland

4 mm to 7.8 mm (0.16" to 0.31")

8

4 mm to 7.8 mm (0.16" to 0.31")

9.9 mm to 14.2 mm (0.39" to 0.56")

5
2

Model#

Connection Type

8800-8-2

10-Pin Bulkhead

Table 13 - Gland Seal Node Models

B.2.2 Bulkhead (8800-1-2_ and 8800-3-2_)

For use with sensor cables that have a male, 10-pin bulkhead connector attached. The
sensor cable is connected to the Node via an external female, 10-pin bulkhead connector
(see Section 2.3.2).

Table 14 - 10-Pin Bulkhead Node Models

B.3 Multiplexer

Multiplexer model types are distinguished by their sensor connection options.

B.3.1 Gland Seal (8800-8-1 and 8800-8-3)

For use with sensor cables that have stripped and tinned ends. The sensor cables pass
through external cable glands and are wired into the terminal blocks according to Section

3.3.2.

Model # Connection Type

8800-8-3 Cable Gland

Table 15 - Gland Seal Multiplexer Models

B.3.2 Bulkhead (8800-8-2)

For use with sensor cables that have a male, 10-pin bulkhead connector attached. The
sensor cables are connected to the Multiplexer via external female, 10-pin bulkhead
connectors (see Section 3.3.1).

Table 16 - 10-Pin Bulkhead Multiplexer Models

B.4 Addressable Sensor Nodes

Model #

Cable Connection

Frequency

Region

8800-5-1A

Cable Gland

2.4 GHz

North America

8800-5-1B

Cable Gland

2.4 GHz

International

8800-6-1A

Cable Gland

900 MHz

North America

8800-6-1B

Cable Gland

900 MHz

Brazil

8800-6-1C

Cable Gland

900 MHz

Australia

Model #

Cable Connection

Frequency

Region

8800-5-2A

5-Pin Bulkhead

2.4 GHz

North America

8800-5-2B

5-Pin Bulkhead

2.4 GHz

International

8800-6-2A

5-Pin Bulkhead

900 MHz

North America

8800-6-2B

5-Pin Bulkhead

900 MHz

Brazil

8800-6-2C

5-Pin Bulkhead

900 MHz

Australia

Addressable Sensor Nodes are used to read Addressable MEMS sensors. Model types are
distinguished by radio output, as well as their sensor connection options.

B.4.1 Gland Seal (8800-5-1_ and 8800-6-1_)

For use with sensors cables with stripped and tinned ends. The sensor cable passes
through an external cable gland and is wired into the terminal block according to Section

4.1.

Table 17 - Gland Seal Addressable Sensor Node Models

B.4.2 Bulkhead (8800-5-2_ and 8800-6-2_)

For use with sensor cables that have a male, 5-pin bulkhead connector attached. The
sensor cable is connected to the Node via an external female, 5-pin bulkhead connector

27

Table 18 - 5-pin Bulkhead Addressable Sensor Node Models

28

Terminal Strip

Position

VW+

Vibrating Wire +

RED

VW-

Vibrating Wire -

BLACK

TH+

Thermistor +

WHITE

TH-

Thermistor -

GREEN

S

Analog Ground (shields)

BARE WIRE

10 Pin Bulkhead

Internal Wire Color

Description

Cable Wire Color

A

Brown

Vibrating Wire +

RED

B

Red

Vibrating Wire -

BLACK

C

Orange

Thermistor +

WHITE

D

Yellow

Thermistor -

GREEN

E

Green

Analog Ground (shields)

BARE WIRE

F

Blue

+VCC Supply

N/A

G

Violet

Digital Ground

N/A

H

Grey

Mux Reset

N/A

J

White

Mux Clock

N/A

K

Black

Digital Ground

N/A

10 Pin Bulkhead

Internal Wire Color

Description

Connection

Brown

J1-1

Green

J1-5 B Red

RX

J1-2

C

Yellow

TX

J1-4

J

12V Aux In (Red)

J3-1

K

GND (Black)

J3-2

10 Pin Bulkhead

Internal Wire Color

Description

J9

A

Red

+5V

2

B

Orange

D-

3 C Yellow

D+

4 D Brown

1

Green

5

APPENDIX C. CONNECTOR PINOUTS

C.1 Transducer Cable Connections

C.1.1 Cable Gland, Models 8800-1-1_ and 8800-3-1_

Description Cable Wire Color

Table 19 - Transducer Cable Connections (Gland Seal)

C.1.2 10-Pin Bulkhead, Models 8800-1-2_ and 8800-3-2_

Table 20 - Transducer Cable Connections (10-Pin Bulkhead)

C.2 Communication Connections

C.2.1 RS-232, Models 8800-2-1_ and 8800-4-1_

A

Red and Black (twisted pair)

Table 21 - Communication Connections (RS-232)

C.2.2 USB, Models 8800-2-2_ and 8800-4-2_

Table 22 - Communications Connections (USB)

GND

GND

29

APPENDIX D. MODBUS

D.1 Protocol

The Supervisor protocol is Modbus RTU. Information about Modbus can be found here:

http://www.modbus.org/specs.php

D.2 Supported Modbus Commands

Modbus was originally developed for communicating with programmable logic controllers.
Many Modbus commands do not make sense with respect to modern embedded devices. GeoNet
Supervisors utilizes four commands:

(0x03) Read Holding Registers
(0x04) Read Input Registers
(0x06) Write Single Register
(0x10) Write Multiple Registers

D.3 Connections Settings

115.2 kbps, eight data bits, one stop bit, no parity, no flow control.

D.4 Special Considerations for GeoNet

GeoNet is an ultra-low-power network. More than 99% of the time, the devices that comprise the
network are in deep sleep. Master devices must recognize busy responses and retry. On first
communication, a busy response is almost a certainty. The Supervisor will stay awake for one
minute after the last communication to be more responsive if subsequent requests are made.

D.5 System Info Table

The system info table provides basic metadata as well as the network time. A newly powered
network will not start acquiring data until the time has been set. This can be accomplished with
Agent software or by writing the time to addresses 0xE20-0xE22. The time does not persist
through battery replacement.

30

Address (hex)

R/W

Data

Type

0xE00 R Firmware Version

uint16_t

0xE02 R Debug Version

uint16_t

0xE0A R Alarm Minutes

uint16_t

0xE0C

R

Temp Command Code

NA

0xE0F R Serial Number LSW

0xE11

R/W

Modbus Timeout (seconds)

uint16_t

0xE13

R/W

Time Zone Offset Minutes

int16_t

0xE14

R/W

Seconds / Minutes

uint8_t/uint8_t

0xE16

R/W

Month / Year

uint8_t/uint8_t

0xE01 R Hardware Version uint16_t

0xE09 R Configuration bitfield

0xE0B R Minutes uint16_t

0xE0D R Channel uint16_t

0xE0E R RTC Calibration uint16_t

0xE11 R Serial Number MSW

uint32_t

0xE12 R/W Scan Rate (minutes) uint16_t

0xE15 R/W Hour / Day uint8_t/uint8_t

0xE17 R/W* Address MSW (only used on reads) uint16_t

Table 23 - System Info and Settings

D.6 Node Tables

Every Node that successfully joins the network will be represented in the Node tables that begin
at 0xE7D. There are 100 tables, each with 20 registers. There will never be any gaps in the table.
This is done so that the master device may build a list of Nodes by reading the tables until an
unpopulated table is encountered. An empty Node will have a serial number of zero.

Table 24 - Node Table Detail

31

Data can be collected from the Node tables at a query interval equal to or less than the scan
interval. Readings will appear in the Node tables as soon as they are successfully communicated
from each Node to the Supervisor. The contents of channel zero through channel nine depends
on the code at offset four (address 0xE95 in this example).

It is possible to miss data if only querying the Node tables. If two successive data packets for a
particular Node arrive, only the second one will be stored in the Node table, regardless of the
time stamps.

Table 25 - Channel Detail (Single Channel Node)

Readings that fall on odd times (not on the scan interval) will have zero as the data array number
to distinguish them from normal readings. When a Node first joins the network with a valid scan
rate and time, it will take a reading at the top of the next minute, regardless of the scan rate.
These readings may fall on odd times.

D.7 Extended Memory

When using Multiplexers, only Node data with code 0xD0 will reside in the Node data table
(Table 24 on the previous page). To access all historical data, Modbus masters must be
programmed to read the extended memory in the Supervisor. Extended memory is divided up
into 1,048,576 readings of 16 registers (32 bytes) each. Data read from external flash needs to be
treated according to the code stored in the first byte of the first register.

The 16 register reading detail is shown in Table 26. The first external memory data array starts at
Modbus register 0x40000 (Page = 4, Address = 0) and the last at 0x103FFF0 (Page = 0x103,
Address = 0xFFF0).

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Figure 21 - External Flash Read Flow Diagram

Table 26 - Data Array Details (EXT Memory)

D.8 Conversions

The following equations can be used to obtain real numbers for the various sensors.

D.8.1 Battery Voltage

Raw

v=5* 



16383

Raw = value from table
v = volts

D.8.2 Board Temperature

Raw

mV=2.5* 

* 1000

16383

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Tb-(T

T=

2

-4Ta(Tc-mV))

b

2T

a

Raw = value from table

mV = millivolts

mV

Ta = -0.00262

C°

2

Tb = 8.194 mV/C°
Tc = 1324 mV
T = Temperature (C°)

D.8.3 Thermistor

3,000Ω*16383

RTH=

-6,000Ω

Raw

1

T=

A+B ln RTH+C (ln RTH)

-273.15°C

3

Raw = value from table
RTH = thermistor resistance Ω

A = 1.4051e-3
B = 2.369e-4
C = 1.019e-7

T = Temperature (C°)

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D.9 Data Types

uint8_t = unsigned 8 bit integer
int8_t = signed 8 bit integer
uint16_t = unsigned 16 bit integer
int16_t = signed 16 bit integer
uint32_t = unsigned 32 bit integer
int32_t = signed 32 bit integer
uint64_t = unsigned 64 bit integer
int64_t = signed 64 bit integer
IEEE-754 = single precision

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Switch #

1 2 3

4

Setting

OFF

OFF

ON

ON

APPENDIX E. SENSEMETRICS MANAGEMENT PLATFORM

GeoNet Wireless nodes are compatible with the Sensemetrics sensor management platform. This
combination of technologies greatly expands the ways in which data can be collected remotely,
with “plug and play” connectivity and with the ability to be displayed in near real-time on a user­friendly, browser-based data platform. Figure 22 shows a network configuration pairing GeoNet
wireless devices with Sensemetrics’ sensor management platform. No GeoNet supervisor is
necessary in this configuration.

Figure 22 - Example Network Configuration

E.1 Channel Configuration

The channel select dipswitch must be set as shown in below in order to communicate with the
Sensemetrics portal. For more information on channel configuration, see Section 2.2.

Figure 23 - Channel Setting for Sensemetrics Compatibility Mode

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E.2 Status Button

When the status button is pressed, nodes indicate their connection status with the network by
briefly illuminating the LED indicators located above the status button. A red flash means the
node has not yet discovered and joined the network. A green flash means the node has joined the
network and is operating. A node with a green flash will be present in the portal. With an
“always on” thread, nodes should join and be present in the portal within a couple of minutes,
provided they are within radio range.

A node with a red flash may be out of radio range of the Sensemetrics gateway (thread) or the
thread may be in low power mode. When adding a node to network, threads should be in “always
on” mode for the fastest deployment. Threads may be switched back to the desired mode once all
the devices are accounted for. The mode of the thread is controlled in the “Modify Thread
Connection” dialog in the portal.

APPENDIX F. FIRMWARE UPGRADE

F.1 Procedure

To perform a firmware upgrade on a Node or Supervisor, complete the following:

1) Power off the unit by moving the battery select switch to the “OFF” position (Figure 24), or
by disconnecting the external battery. (For units manufactured prior to June 2017, which do
not have an OFF position, remove the D cells from the battery holder.)

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Figure 24 - Battery Selector Switch in OFF Position

2) Ensure that the unit is completely discharged of electrical potential by pressing the status
button repeatedly until no LED lights flash.

3) For RS-232 Supervisors: Connect the 8001-7 USB to RS-232 adapter cable to the COM­108 RS-232 to 10-pin cable. Continue to step four.
For all other Nodes/Supervisors: Connect the B8800-5 upgrade cable to the “RS232 J1”
connector on the bottom circuit board. (See Figure 25 for connector detail.)

Figure 25 - J1 Connector Detail

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4) Connect the B8800-5 upgrade cable to the 8001-7 USB to RS-232 adapter cable, and then
connect the 8001-7 USB to RS-232 cable to the computer. See Figure 26 for the completed
set up.

Figure 26 - Upgrade Cable Detail

5) Move all channel select dipswitches to the “On” position (Figure 27).

Figure 27 - Channel Selector Switch

6) Move the battery select switch to either the “Alkaline” or “Lithium” position depending on
the type of battery being used. Reconnect the external battery if equipped. (For units
manufactured prior to June 2017, which do not have an OFF position, reinstall the D cells
into the unit.)

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7) The green LED indicator on the right side of the unit will flash in one-second intervals.

8) Run the GeoNet Firmware Updater program.

9) Click “Select File” and choose the latest firmware file. (Firmware files are named in the
following format: “GeoNet_Firmware_YYMMDD.txt”, where YY is the last two digits of
the year, MM is the month, and DD is the day of the month.)

10) Using the drop down box below the “Select File” button, select the correct serial port for the
8001-7 USB to RS-232 cable. To identify which serial port the unit is connected to, open
Device Manager by completing the following:
a) Go to “Control Panel” then “Device Manager”.
b) Click on the triangle to the left of “Ports (COM & LPT)” to expand the list.
c) Once the cable is plugged in the port will appear in the list.

11) Click “Program”. A progress bar will appear and the process will take one to two minutes
(Figure 28).

Figure 28 - Update Progress

12) Power off the unit by moving the battery select switch to the “OFF” position (Figure 24), or
by disconnecting the external battery. (For units manufactured prior to June 2017, which do
not have an OFF position, remove the D cells from the battery holder.)

13) Ensure the unit is completely discharged of electrical potential by pressing the status button
repeatedly until no LED lights flash.

14) Return the channel select dip switches to the desired channel setting.

15) Power on the unit by moving the battery select switch to either the “Alkaline” or “Lithium”
position depending on the type of battery being used. Reconnect the external battery if
equipped. (For units manufactured prior to June 2017, reinstall the D cells into the unit.)

The firmware upgrade is now complete.

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F.2 Troubleshooting

 Make sure the green light is flashing on and off in one second intervals.

 The B8800-5 multicolored upgrade ribbon cable must be used on all units with the exception

of the RS-232 version supervisor.

 Updates should be done using the Geokon provided 8001-7 USB to RS232 adapter. Other

adapters and native serial ports have been unreliable.

 Make sure the batteries are fresh.