1 introduction, 2 conversion modes, 1 oversample ratio – Sensoray 2600 User Manual

2600 Family Instruction Manual

43

Chapter 8 : Model 2612 Strain Gauge/RTD Module

Chapter 8: Model 2612 Strain Gauge/RTD Module

8.1 Introduction

Model 2612 is a smart I/O module (IOM) that has four sensor
interface channels that are optimized for precision
measurement of passive resistive devices such as strain gauges,
RTDs and thermistors. The 2612 may be connected to any
IOM port on a model 2601 main module (MM) by means of a
single Cat-5 cable.

Each channel consists of an independent, fully differential
analog-to-digital converter (ADC) and a programmable
excitation generator. The ADC has inputs for both the
differential sensor signal and a differential reference voltage,
thus enabling the ADC to eliminate gain errors via ratiometric
conversion.

Figure 38: Model 2612 Block Diagram

Analog input subsystems include special circuitry that
implement fully electronic calibration. Excellent long-term
accuracy is achieved through the combination of high quality
on-board reference standards and the total absence of
mechanical trims.

The module’s electrical connectors are optimized for direct
connection to field wiring, in most cases eliminating the need
for external field wiring termination systems. All field wiring
is attached directly to the module by means of pluggable
connectors so that downtime will be minimized should it
become necessary to replace a module.

The entire module is automatically reset by a built-in watchdog
timer if an internal fault develops. Also, the module
automatically resets if the MM fails to communicate to it
within a programmable time interval.

Diagnostic LEDs include Power, Heartbeat, and
communication status. A self-test is performed automatically at
power-on and reset, and any detected fault conditions are
displayed on the status indicators.

A high-efficiency, on-board power supply produces all
required operating voltages from a single 24VDC source,
which is obtained from the MM via the module’s IOM port.
Test points are provided for all power supply voltages and
analog I/O signals.

8.2 Conversion Modes

Each channel is assigned a “conversion mode,” which specifies
its input conversion rate. This mode specifier has two parts:
the Oversample Ratio and Speed Multiplier.

8.2.1 Oversample Ratio

The oversample ratio (OSR) determines a number of
operational parameters as shown in Table 21.

Table 21: Behavior for various OSR settings

For example, with OSR=32768, the first null (notch) of the
digital filter occurs at approximately 55 Hz. This setting
provides better than 80dB rejection in the range from 49Hz to
61Hz.

Rejection of the first notch frequency and its multiples (up to
1.8MHz) exceeds 120dB. Effective noise bandwidth is a
measure of how the ADC will reject wideband input noise up
to the sample rate.

8.2.2 Speed Multiplier

The speed multiplier, which is used to double the input
conversion rate, may be enabled or disabled for each channel.
All other parameters (e.g., RMS Noise, Effective Bits) in Table
21 are unaffected by the speed multiplier. One additional cycle
of latency will be inserted between input signal and output data
when the speed multiplier is active.

µC

Input

IOM
Port

To 2601
IOM Port

Status
LEDs

Power
Supply

ADC

ADC

Power
Supply

Reference

Excitation

Chan0

Input

ADC

ADC

Power
Supply

Reference

Excitation

Chan1

Input

ADC

ADC

Power
Supply

Reference

Excitation

Chan2

Input

ADC

ADC

Power
Supply

Reference

Excitation

Chan3

OSR

RMS
Noise

Conversion
Rate (Hz)

First Notch
(Hz)

–3dB Point
(Hz)

Effective
Bits

64

23µV

3515.6

28125

1696

17

128

4.5µV

1757.8

14062.5

848

20.1

256

2.8µV

878.9

7031.3

424

20.8

512

2µV

439.5

3515.6

212

21.3

1024

1.4µV

219.7

1757.8

106

21.8

2048

1.1µV

109.9

878.9

53

22.1

4096

720nV

54.9

439.5

26.5

22.7

8192

530nV

27.5

219.7

13.2

23.2

16384 350nV

13.75

109.9

6.6

23.8

32768 280nV

6.875

54.9

3.3

24.1