AB Soft Recording Equipment Mercury 3000Si User Manual

Preliminary  
Mercury 3000Si Dual Axis Averager  
Motion Control Feedback Using Averaging of Two Sensors  
Installation Manual  
and Reference Guide  
Manual No. IM-M3000SiDAA Rev S4  
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Table Of Contents  
SYSTEM ILLUSTRATION  
Encoder with Linear scale  
Encoder with Rotary scale  
PAGE  
2
3
INSTALLATION INSTRUCTIONS  
Encoder System Mounting - Linear  
Encoder System Alignment - Linear  
Centering the Index & Calibration - Linear  
Encoder System Mounting - Rotary  
Encoder System Alignment - Rotary  
Centering the Index & Calibration - Rotary  
4
5
5
6
7
7
REFERENCE SECTION  
Installation of Linear Scales  
Grounding Instructions  
8
9
Recommendations for Power  
Customer Interface Cable Requirements  
Serial Output Specifications  
9
10  
11-12  
SMARTPRECISION SOFTWARE INSTALLATION  
13-19  
SPECIFICATIONS  
Operating and Electrical  
20  
20  
21  
21  
22  
23  
24  
Output Connector Pinout  
Serial Output  
Operational Modes: Standard Communication  
Serial Output Specificattion  
Operational Modes - Trigger Approach Diagram  
Serial Data Format  
ENCODER TROUBLESHOOTING  
Selected Topics  
24  
25  
Cleaning Scales  
Back Cover  
PrecautionsContact MicroE Systems  
Follow standard ESD precautions. Turn power off before connecting the sensor.  
Do not touch the electrical pins without static protection such as a grounded wrist strap.  
1
Do not touch the glass scale unless you are wearing talc-free gloves or finger cots.  
Please read this installation manual for full instructions.  
2
Safety Information  
MicroE Systems Mercury series reflective encoders are classified as CDRH Class I and IEC Class 1M laser products.  
• Invisible laser radiation (wavelength: 850 nm). Max power 1.5 mW CW.  
• This product conforms to all applicable standards under 21 CFR Ch. I 1040.10.  
• CDRH Class I level of laser radiation is not considered to be hazardous.  
• CAUTION - The use of optical instruments with this product will increase eye hazard.  
DO NOT VIEW DIRECTLY WITH OPTICAL INSTRUMENTS  
(MICROSCOPES, EYE LOUPES OR MAGNIFIERS)  
CLASS 1M LASER PRODUCT  
IEC 60825-1 (2001)  
Patents  
Covered by the following patents: US 5,991,249; EP 895,239; JP 3,025,237; US 6,897,435; and EP 1,451,933.  
Additional patents and patents pending may apply.  
Page 1  
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Mercury 3000Si Encoder System  
with Linear scale  
System View  
Shown with linear scale  
Glass scale  
(shown mounted on a linear slide)  
Sensors  
(shown attached on a linear slide base with  
mounting brackets)  
Dual Axis/SmartPrecision electronics module  
(interpolator)  
Double  
shielded cables  
Expanded View  
Mounting screws & flat  
washers (2 needed per  
screw)  
Sensor 2  
Sensor mounting holes (2)  
Optional sensor benching pins (3)  
Sensor 1  
Typical user-supplied  
sensor mounting brackets  
End locator pin  
Cover: Sensor cables  
and connectors  
Center index mark  
Bracket mounting  
holes (2) per  
sensor  
Power/Calibration -  
Sensor 2  
Signal - Sensor 2  
USB interface  
Scale reference datum;  
example shown with benching pins  
Index Calibration Button - Sensor 1 and 2  
Power/Calibration - Sensor 1  
Signal - Sensor 1  
Detail A  
25 pin High Density  
D-sub connector  
Top reflective linear scale  
End index mark  
Scale benching edge  
Page 2  
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Mercury 3000Si Encoder System  
with Rotary scale  
System View  
Shown with Rotary scale  
Sensors  
(shown attached to a customer-supplied  
mounting brackets)  
Rotary scale  
Dual Axis/SmartPrecision electronics module  
(interpolator)  
Expanded View  
Mounting screws & flat  
washers (2 needed per screw)  
Sensor 1  
Sensor 2  
Double  
shielded cable  
Mounting hole (2)  
Typical user-supplied  
sensor mounting bracket  
Top reflective  
rotary scale  
Rotary scale  
PowerPower/Calibration -  
Sensor 2  
Signal - Sensor 2  
Power/Calibration - Sensor 1  
Signal - Sensor 1  
USB interface  
Index Calibration Button - Sensor 1 and 2  
25 pin High Density  
D-sub connector  
Page 3  
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Installation Instructions  
Linear Encoders - Mounting  
Install the sensors on your mounting surfaces  
referencing the appropriate datum surface as  
shown on the interface drawing. Use 2 washers  
per mounting screw.  
Benching pins may be used to locate each sensor  
if the system mechanical tolerances are adequate.  
See data sheet for alignment tolerances, or keep  
mounting screws loose for sensor alignment if  
benching pins are not used.  
2
Attach the scale to the base  
slide. Reference the preferred  
datum on the interface drawing  
for either end or center index  
orientation.  
1
Depending on the mounting  
method, attach the scale to the  
slide with adhesive. Refer to pg.  
8 for details.  
Be sure the grating surface of  
the scale faces the sensor.  
Insure that there is no contact  
between these surfaces or  
damage may result.  
Be sure the source power is off before  
connecting the SmartPrecision plug.  
Connect the SmartPrecision electronics to the  
controller using the pinout diagram described on the  
interface drawing.  
4
Insure proper system grounding. Refer to the proce-  
dure on pg 9.  
CAUTION: observe precautions for handling elec-  
trostatic sensitive devices.  
Tighten the thumb screws.  
Route the sensor cables through your equipment  
to the Dual Axis SmartPrecision electronics module.  
Power up the system. The Power and Signal indica-  
tors for both sensors will illuminate.  
A) Remove the three cover screws and the top  
half of the connector housing. Do not pull on  
Sensor 1  
the 25-pin D-sub connector or the circuit  
board under the insulation layer.  
3
B) Attach each sensor's 5 X 2 connector to the  
mating 5 X 2 connector on the circuit board.  
C) Route the sensor cables through their channels  
in the center of the connector body and place  
the cable's hex sleeves in the matching recesses.  
Attach the top half of the connector housing  
to the bottom half using the three cover screws.  
Sensor 2  
Page 4  
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Installation Instructions  
Linear Encoders - Alignment  
If benching dimensions cannot be provided, proper sensor alignment may require minor  
adjustments to each sensor’s position with respect to the scale. This can be performed easily  
using the LED alignment indicators, as illustrated below.  
θz  
For sensor 1, the Sig 1 multicolor LED will turn from red to yellow-orange to green depending  
on sensor alignment. Slowly move the sensor by allowing it to slide on the mounting surface  
until the Sig 1 multicolor LED turns green. Optimal alignment will be displayed as a “Bright  
Green” LED. Repeat the last step, using sensor 2 and the Sig 2 multicolor LED, to align  
sensor 2.  
5
Z
IMPORTANT: Confirm that the Proper Alignment LED blinks when passing over the index.  
If not, readjust the sensor in the Y direction and repeat the above procedure. When alignment is  
completed, tighten the sensor mounting screws (0.37Nm [3.3 inch-lbs.] maximum torque).  
To align the sensor, move it  
in the Y or θ directions.  
z
Proper  
Alignment LED  
Green:  
Improper  
Alignment LED  
Red:  
Improved  
Alignment LED  
Yellow-Orange:  
Sensor 1  
Sensor 1  
Sensor 1  
Power/  
Calibration  
Sensor 1  
Power/  
Calibration  
Sensor 1  
Power/  
Calibration  
Sensor 1  
Proper  
Alignment LED  
Green:  
Improper  
Alignment LED  
Red:  
Improved  
Alignment LED  
Yellow-Orange:  
Sensor 2  
Sensor 2  
Sensor 2  
Power/  
Calibration  
Sensor 2  
Power/  
Calibration  
Sensor 2  
Power/  
Calibration  
Sensor 2  
IMPORTANT  
OUTPUT CALIBRATION PROCEDURE  
Confirm proper alignment over  
the full range of motion.  
This procedure must be completed for proper system  
operation each time the sensors are aligned or if the  
SmartPrecision electronics module is replaced  
Position each sensor at least 7mm (1/4”) away from the index  
mark on the scale. Next, for sensor 1, push the  
Index/Calibration button inside the module just once. The  
Power/Calibration indicator for sensor 1, will flash continuously.  
Move the scale past sensor 1 in both directions so that the  
index mark passes under sensor 1. When the calibration pro-  
cedure is complete, the Power/Calibration indicator for sensor 1  
stops flashing.  
7
The “Proper Alignment” LED  
must remain green over the  
entire range for both sensors.  
If not aligned over the entire  
range of motion, loosen the  
sensors mounting screws and  
repeat step 5.  
6
To calibrate sensor 2, push the Index/Calibration button twice. The  
Power/Calibration indicator for sensor 2 will flash continuously.  
Move the scale past sensor 2 in both directions so that the  
index mark passes under sensor 2. When the calibration pro-  
cedure is complete, the Power/Calibration indicator for sensor 2  
stops flashing.  
Sensor 1: Proper  
Alignment indicator  
Sensor 2:  
Calibration / Index  
Set Up button  
Push twice.  
Sensor 1:  
Calibration / Index  
Set Up button  
Sensor 2: Proper  
Push once.  
Alignment indicator  
Sensor 1: Power/  
Calibration indicator  
Sensor 2: Power/  
Calibration indicator  
Page 5  
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Installation Instructions  
Rotary Encoders - Mounting  
Install the sensors on your mounting surface referencing the  
appropriate datum surface as shown on the interface drawing.  
Use 2 washers per mounting screw.  
2
Benching pins may be used to locate each sensor if the system  
mechanical tolerances are adequate. See data sheet for alignment  
tolerances, or keep mounting screws loose for sensor alignment if  
benching pins are not used.  
Attach your hub/scale  
assembly to the rotary  
device. Refer to the  
interface drawing. The  
reflective surface of the  
scale must face the  
sensors.  
1
Be sure the source power is off before  
connecting the SmartPrecision plug.  
Connect the SmartPrecision electronics to the controller  
using the pinout diagram described on the interface  
drawing.  
4
Insure proper system grounding. Refer to the procedure  
on pg 9.  
CAUTION: observe precautions for handling elec-  
trostatic sensitive devices.  
Power up the system. The Power and Signal indicators for  
both sensors will illuminate.  
Route the sensor cables through your equipment  
to the Dual Axis SmartPrecision electronics module.  
A) Remove the three cover screws and the top  
half of the connector housing. Do not pull on  
Sensor 1  
the 25-pin D-sub connector or the circuit  
board under the insulation layer.  
3
B) Attach each sensor's 5 X 2 connector to the  
mating 5 X 2 connector on the circuit board.  
C) Route the sensor cables through their channels  
in the center of the connector body and place  
the cable's hex sleeves in the matching recesses.  
Attach the top half of the connector housing  
to the bottom half using the three cover screws.  
Sensor 2  
Page 6  
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Installation Instructions  
Rotary Encoders - Alignment  
If benching dimensions cannot be provided, proper sensor alignment may require minor  
adjustments to each sensor’s position with respect to the scale. This can be performed easily  
using the LED alignment indicators, as illustrated below.  
θz  
For sensor 1, the Sig 1 multicolor LED will turn from red to yellow-orange to green depending  
on sensor alignment. Slowly move the sensor by allowing it to slide on the mounting surface  
until the Sig 1 multicolor LED turns green. Optimal alignment will be displayed as a “Bright  
Green” LED. Repeat the last step, using sensor 2 and the Sig 2 multicolor LED, to align  
sensor 2.  
5
Z
IMPORTANT  
: Confirm that the Proper Alignment LED blinks when passing over the index.  
If not, readjust the sensor in the Y direction and repeat the above procedure. When alignment is  
completed, tighten the sensor mounting screws (0.37Nm [3.3 inch-lbs.] maximum torque).  
To align the sensor, move it  
in the Y or θ directions.  
z
Proper  
Alignment LED  
Green:  
Improper  
Alignment LED  
Red:  
Improved  
Alignment LED  
Yellow-Orange:  
Sensor 1  
Sensor 1  
Sensor 1  
Power/  
Calibration  
Sensor 1  
Power/  
Calibration  
Sensor 1  
Power/  
Calibration  
Sensor 1  
Proper  
Alignment LED  
Green:  
Improper  
Alignment LED  
Red:  
Improved  
Alignment LED  
Yellow-Orange:  
Sensor 2  
Sensor 2  
Sensor 2  
Power/  
Calibration  
Sensor 2  
Power/  
Calibration  
Sensor 2  
Power/  
Calibration  
Sensor 2  
IMPORTANT  
OUTPUT CALIBRATION PROCEDURE  
Confirm proper alignment over the full range of motion.  
The “Proper Alignment” LED must remain green over the entire  
range for both sensors. If not aligned over the entire range of  
motion, loosen the sensors mounting screws and repeat step 5.  
This procedure must be completed for proper system  
operation each time the sensors are aligned or if the  
SmartPrecision electronics module is replaced  
Position each sensor at least 7mm (1/4”) away from the index  
mark on the scale. Next, for sensor 1, push the  
7
6
Index/Calibration button inside the module just once. The  
Power/Calibration indicator for sensor 1, will flash continuously.  
Move the scale past sensor 1 in both directions so that the  
index mark passes under sensor 1. When the calibration pro-  
cedure is complete, the Power/Calibration indicator for sensor 1  
stops flashing.  
To calibrate sensor 2, push the Index/Calibration button twice. The  
Power/Calibration indicator for sensor 2 will flash continuously.  
Move the scale past sensor 2 in both directions so that the  
index mark passes under sensor 2. When the calibration pro-  
cedure is complete, the Power/Calibration indicator for sensor 2  
stops flashing.  
Sensor 1: Proper  
Alignment indicator  
Sensor 2:  
Move the scale past both  
sensor s so that the index  
mark passes under both  
sensors as described in  
step 7.  
Calibration / Index  
Set Up button  
Push twice.  
Sensor 1:  
Calibration / Index  
Set Up button  
Sensor 2: Proper  
Push once.  
Alignment indicator  
Sensor 1: Power/  
Calibration indicator  
Sensor 2: Power/  
Calibration indicator  
Page 7  
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Reference Section  
Installation of Linear Scales  
Positioning the Scale  
Note: Before beginning mounting procedure, use talc-free gloves or finger cots to handle the scales.  
"Benching" the scale to the system means aligning the scale by means of benching pins. Pin locations are described on the appropriate interface drawing.  
Two benching pins are recommended on the long side of the scale and one at the end as shown . This is marked datum A on the interface drawing.  
Position the benching pins in from either end. 20% of the overall  
Be sure the benching pins do not extend too high in the Z direction to  
1 scale length is the recommended location from the edge.  
2prevent mechanical interference with the sensor or sensor mount.  
0.6L  
L
0.2L  
0.2L  
End  
Benching  
Pin  
MicroE Systems  
Benching pins  
Mounting the Scale  
MicroE Systems' linear scales should be affixed to the mounting surface. Two different approaches are described below:  
Epoxy and RTV Mounting (Recommended for best accuracy)  
Scale clamp  
Optionally, scale clamps may be used to secure the  
with adhesive  
3scale while the adhesive cures. Avoid damage to  
Make sure the mounting surface is  
the top surface.  
1 clean and dry.  
Side view showing  
optional scale clamps  
and scale. Space  
clamps every 75mm  
on scales over 150  
mm in length.  
End Benching  
Pin  
L
Mounting clamp  
Mounting clamp  
Hard epoxy  
MicroE Systems  
at one corner,  
this end only.  
Mounting clamp  
RTV around entire  
Benching pins  
outside edge of scale.  
Align the scale by placing the edges against the benching pins.  
2
Apply a hard epoxy, such as Tra-Con’s Tra-Bond 2116, to the end of the scale at the end benching pin. Apply 100% Silicone RTV adhesive  
4 around the edges of the scale. This method allows thermal expansion from the benched end of the scale. After adhesive curing, remove  
the scale mounting clamps or, if permanently installing clamps, make sure they do not interfere with the sensor or sensor mount.  
Two Sided Adhesive Tape Mounting  
Gently place the scale on the mounting surface. Positioning adjustments  
3 can be made until the scale is firmly pressed down. After final positioning,  
push down on the top of the scale to secure it.  
Make sure the mounting surface is clean and dry. Peel the  
cover paper off and place the scale above the final location.  
1
End Benching  
Pin  
L
Hard epoxy at  
one corner,  
MicroE Systems  
Benching pins  
this end only.  
Align the scale by placing the edges against the benching pins.  
2
Page 8  
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Reference Section  
Grounding Instructions for Mercury 3000Si Dual Axis Encoder Systems  
For Mercury 3000Si Dual Axis Averager encoder systems to operate reliably, it is essential that the sensor and cable shield are ground-  
ed properly according to the following instructions. The diagrams below show how to make the connections when the encoder's con-  
nector is plugged into the customer's controller chassis. If a customer-supplied extension cable is used, it should be a double shielded  
cable with conductive connector shells and must provide complete shielding over the conductors contained within it over its entire  
length. Furthermore, the shields should be grounded at the connection to the controller chassis the same way as the encoder connec-  
tors in the diagrams below.  
Note: For best performance, isolate encoder shield from motor cable shields and separate encoder cable as far possible from motor cables.  
Sensors mounted with good electrical contact to a well-grounded surfaces (preferred)  
1. 25-pin D-sub connector grounding: The encoder's connector shell must be in intimate, electrically conductive contact with the customer-  
supplied mating connector, which must be isolated from the controller's ground. If a customer-supplied shielded cable connects the encoder  
to the controller, then the shielding on the customer-supplied cable must be isolated from the controller's ground.  
2. The sensors’ mounting surfaces must have a low impedance (DC/AC) connection to ground. The encoder sensors’ mounting surfaces may have  
to be masked during painting or anodizing to insure good electrical contact with the sensors.  
Electrically conductive  
mechanical connection  
(as supplied by MicroE  
Systems).  
Inner Shield: Insulated from outer shield,  
sensor and connector housing. Connected  
to circuit common internally.  
Outer Shield: Connect to sensor  
and connector housing.  
Do not ground shroud.  
Sensors mounted to a surfaces that are grounded through bearings or poorly-grounded surfaces, or non-conducting surfaces  
1. 25-pin D-sub connector grounding: The encoder's connector shell must be in intimate, electrically conductive contact with the customer-supplied mating  
connector, which must be connected to the controller's ground. If a customer-supplied shielded cable connects the encoder to the controller, then the  
shielding on the customer-supplied cable must be connected to the controller's ground. The controller must be grounded to earth at the point of installation.  
2. The encoder sensors must be mounted so that they are electrically isolated from ground.  
Recommendations for Power  
Mercury encoders require a minimum of 4.75V DC continuously. When designing circuits and extension cables to use Mercury encoders, be sure to  
account for voltage loss over distance and tolerances from the nominal supply voltage so that at least 4.75V DC is available to the Mercury encoder  
under all operating conditions. The input voltage should not exceed 5.25V DC.  
Page 9  
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Customer Interface Cable Requirements  
Customer cables that interface to Mercury series encoders must have the following characteristics:  
• Twisted pair signal wiring.  
• Characteristic impedance of 100-120 ohms.  
• Sufficient wire gauge to meet the minimum voltage requirement at the encoder, for example 24AWG gauge wire for a 2m length cable.  
Examples of acceptable cables with 24 AWG gauge wire and 5 twisted pairs are Belden 9832, 8105 or other manufacturer’s  
equivalents.  
• Single shield cable with a minimum of 90% coverage. Note that a double shielded cable may be required in high-noise applications.  
Signal Wiring:  
Each differential signal should be connected to a corresponding twisted pair as follows:  
Mercury 3000SiDAA  
Signal  
Twisted Pair  
SD0+  
SD0-  
Pair 1  
Trigger+  
Trigger-  
SCK+  
SCK-  
Pair 2*  
Pair 3  
Pair 4  
Pair 5  
Revision pending.  
N_CS+  
N_CS-  
+5V  
GND  
* For synchronous system connection only.  
Shield Termination:  
The customer's cable shield should be in 360° contact with the connector shroud and the connector shell to provide complete shielding. The  
connector shell should be metal with conductive surfaces. Suggested metal connector shells for use with Mercury 3500, 3000, 3000Si,  
3000SiDAA, 3000DAA, and 2000 encoders: AMP 748676-1 or equivalent; for Mercury 1000 and 1500S encoders: AMP 745172-3, -2, or -1  
where the dash number is dependent on the customer's outside cable diameter. The shield should be terminated as illustrated in the following  
diagram.  
Fold braided shield back over jacket. Example shows double-shielded cable. Dimensions shown  
are for illustration only.  
Page 10  
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Serial Output Specification  
Introduction  
Historically, the method of choice for many optical position feedback systems has been A quad B (Quadrature) output. The limitation  
of this method is output speed, especially when the interpolation level is high. When the optical sensor speed and/or the  
interpolation multiplier is set high, the Quadrature output frequencies will be extremely high and out of the range of the  
Quadrature counters of most standard motion controllers.  
This limitation can be avoided by sending the position information in parallel format or in a serial word format. The parallel  
formats are cumbersome to cable (especially wide word lengths) and are more susceptible to noise interference. Therefore, a  
serial data word format is the data communication method of choice.  
The Mercury 3000Si Dual Axis Averager Interpolator has the ability to output a position word in a serialized format. This allows  
very fast communication between an interpolator and customer application. The speed limitation of the Quadrature format is  
thus eliminated.  
Signal Description  
The interface from your electronics to the Mercury 3000SiDAA interpolator uses four signals, n_spiEnable (n_CS), spiDataOut  
(SDO), spiClock (SCK), and optional spiTrigger (TRIG). Each signal is differential and RS-422 compatible. See table for interpolator  
signal names, pin names, and pin locations:  
Signal Description  
Signal name  
n_spiEnable  
spiClock  
Pin Name  
Function  
I/O  
15 pin HD  
Connector  
Interpolator  
Referenced  
n_CS+  
n_CS-  
SCK+  
SCK-  
Chip Select+  
Input  
Input  
7
8
Chip Select-  
Serial Clock+  
Input  
14  
15  
5
Serial Clock-  
Input  
spiDataOut  
spiTrigger  
SDO+  
SDO-  
TRIG+  
TRIG-  
Serial Data Out+  
Serial Data Out-  
External Trigger+  
External Trigger-  
Output  
Output  
Input  
4
10  
9
Input  
Revision pending.  
Page 11  
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Serial Output Specification  
Index Processing  
A unique physical position is referenced on all gratings and is called an index position. The value of this position is determined  
during an index capture routine initiated by a button press or the SmartPrecision Software and is permanently stored for use  
after power cycling. The index value has the same resolution as the interpolated position.  
The M3000SiDAA has four modes of operation that use the index position to generate a physical reference position. The posi-  
tion word calculated by the M3000SiDAA electronics is a 28-bit number, which includes 18 fringe counter bits and 10 sub-  
fringe interpolation bits. The fringe counter keeps track of the number of electrical cycles encountered caused by a grating  
moving past a sensor and can be reset. The sub-fringe position is absolute because the voltage relationship between sine and  
cosine are fixed electrically and therefore cannot be reset or cleared.  
A physical mark on the grating called an index window is used to generate an accurate index position. The index window  
is approximately one fringe wide. By monitoring the edges of the window with respect to the absolute sub-fringe position  
during the index capture mode, an accurate index position is calculated and stored.  
At power up the encoder is in an undefined position relative to the outside world. By traveling past the index mark on the scale  
and knowing where the index is relative to the outside world the encoder position becomes defined. The M3000SiDAA sup-  
ports the following index processing modes:  
No Index: No changes are made to the position word at the index mark.  
Mode 1: Zeros the fringe counter at the first encounter with index mark after power up.  
Mode 2: Zeros the fringe counter at every encounter with index mark.  
Mode 3: Zeros the fringe counter at the first encounter with index mark after power up and  
subtracts the index position from the calculated position making the index mark the  
zero position of the encoder.  
Mode 4: Zeros the fringe counter at every encounter with index mark after power up and  
subtracts the index position from the calculated position making the index mark the  
zero position of the encoder.  
The Index mode can be factory set or selected by the customer using the optional SmartPrecision software.  
Page 12  
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Optional SmartPrecision Software Installation Instructions  
Hardware Requirements:  
SmartPrecision Software for M3000SiDAA requires a PC with the following minimum specifications:  
· Windows 2000 or XP operating systems  
· 300MHz  
· 32Mb RAM  
· 1024 x 768 or higher screen resolution with High Color (16 bit color)  
· 20Mb free disk space  
· One USB port (Version 1.1 or higher)  
MicroE SS300cDI SmartPrecision Software (Preliminary)  
Software Notes:  
1) This is Preliminary Software - Functionality not comprehensively tested and some limitations exist.  
2) Intended for use on Windows 2000 or XP systems, with display resolution of at least 1024x768 (1024x768 is  
optimal).  
Installing the Software:  
1) IMPORTANT - INSTALL SOFTWARE BEFORE CONNECTING ELECTRONICS - this will allow the proper driver files  
to be copied to the PC.  
2) Insert Install CD - if setup does not automatically start - navigate to CD folder and run 'setup.exe'  
3) To start the software - Click on 'Start>Programs>MicroE SmartPrecision for SS300cDI>SS300cDI Software' in the  
Start Menu.  
Installing the USB Driver:  
USB Driver Installation Windows 2000:  
1) Connect the USB cable between the host computer and the M3000SiDAA.  
2) When the electronics are on, Windows will notify you it has found new hardware prompting you with a "Found  
New Hardware" wizard. Press the Next button.  
3) Select "Search for a suitable driver for my device (recommended)" and press the Next button.  
4) Select "Specify a location" under "Optional search locations:" and press the Next button.  
5) Press the Browse button to locate the SiF32X_USB.inf driver Installation file. SiF32X_USB.inf is located in  
"Install Directory\Driver" under the directory where the software was installed. The default install directory is  
..Program Files\MicroE Systems\ss300cDI.  
Once this file is selected press the OK button.  
6) Verify that the correct path and filename are shown and press the Next button.  
7) Press the Finish button.  
USB Driver Installation Windows XP:  
1) Connect the USB cable between the host computer and the M3000SiDAA.  
2) When the electronics are on,, Windows will notify you it has found new hardware prompting you with a "Found  
New Hardware" wizard.  
3) Select "Install from a list or specific location(Advanced)" and press the Next button.  
4) Select "Include this location in the search". Press the Browse button to locate the SiF32X_USB.inf driver  
installation file. SiF32X_USB.inf is located in "Install Directory\Driver" under the directory where the software  
was installed. The default install directory is ..Program Files\MicroE Systems\ss300cDI. Once this file is selected  
press the OK button.  
5) Verify that the correct path and filename are shown and press the Next button.  
6) Press the Finish button.  
Page 13  
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Configuration and Setup - SmartPrecision Software  
The M3000SiDAA interpolator module can be configured quickly and easily using the SmartPrecision Software. The M3000SiDAA inter-  
polator will accept input from two separate encoders. The M3000SiDAA has three output channels. These can be configured to output  
the following: Channel 1, Channel 2, Average ((Ch1+Ch2)/2), and/or Difference (Ch1-Ch2). The main screen shows Encoder Position,  
Signal Level, Alarm Status, Data Plots, and Setup.  
Encoder Position:  
The Encoder Position box displays the current position data for each of the three output channels.  
Each output can be reset or zeroed independently. The units can be changed from encoder counts, to any number of linear or rotary units.  
Main Screen  
Setup  
Calibrate: Starts the calibration routine for the selected channel.  
Configure: Allows user to configure the Input and Output Channel settings,  
Calibration settings, SPI settings, and Hardware/Communication  
settings  
Display Settings: Configures the SmartPrecision Software Display  
Data Plots  
Encoder Signal: Displays the encoder signal plot for each input channel  
Signal Strength: Displays the encoder signal strength for each in out channel.  
Encoder Position: Displays the encoder position for each in out channel.  
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M3000SiDAA Configuration  
5
1
2
9
6
7
10  
11  
8
3
4
Configurations screen  
Channel for Average Index:  
Selects the input channel index that will be used for the Averaged output.  
Example shown:  
1
2
Index for Channel 1 selected  
Output Channels [1 - 2 - 3]  
:
The Mercury Dual Axis Averager uses two sensors as inputs and has three output channels. Each sensor's signal is processed for  
accuracy enhancement and interpolated. The signals, or their average or difference, are routed to each of the three output channels.  
The routing assignments can be changed using SmartPrecision Software in the Configuration Settings dialog box. There are four possi-  
ble configurations for the output channel assignments as shown in the following table:  
Output Configuration  
Assignment for Output  
Channel 1  
Assignment for Output  
Channel 2  
Assignment for Output  
Channel 3  
"Channel 1 - Channel 2 - Average"  
"Channel 2 - Channel 1 - Difference"  
"Average - Difference - Channel 1"  
"Difference - Average - Channel 2"  
Sensor 1  
Sensor 2  
Average of Sensor 1  
and Sensor 2  
Difference  
(Sensor 1 minus Sensor 2)  
Sensor 1  
Sensor 2  
Sensor 1  
Average of Sensor 1  
and Sensor 2  
Difference  
(Sensor 1 minus Sensor 2)  
Difference  
(Sensor 1 minus Sensor 2)  
Average of Sensor 1  
and Sensor 2  
Sensor 2  
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M3000SiDAA Configuration  
Channel 1 & 2 Calibration Settings  
3
4
If two separate axes are used the recommended setting is "Calibrate signal and center index". For applications where two  
sensors are used on the same axis or if the index mark is not in the range of motion for one of the encoders, the "Calibrate  
signal only" will allow proper calibration of the signal.  
Fringe Counter Size  
5
The M3000SiDAA allows the user to configure the serial word to increase sampling rate. Some applications do not  
require 18 bits of fringe count. The SPI Settings box allows the user to reduce the fringe counter to suit the applica-  
tion and thereby increasing the maximum sampling rate of the system.  
SPI Output Format  
6
7
The format of the SPI output can be configured to have the status word at the beginning or at the end of the serial  
word.  
SPI Modes  
There are two different SPI modes the users can select from:  
Free Running or Standard communication mode latches the output buffer with the current data when the  
falling edge of Chip Select is asserted.  
The Trigger Acquisition mode can be used in applications where synchronization of the position data to an  
event is required. Often, this mode is used when a fixed latency between a clock signal and the sampled  
position data is required. If this option is selected a new calculation cycle starts each time the falling edge  
of Chip Select is asserted. NOTE: This mode is equivalent to the SS-350cSI Trigger line. It use the falling  
edge of the cs as trigger  
8
Index Mode Settings:  
Configure how the serial word data is manipulated when encountering the index angle position.  
Master Chip Select  
9
Allows one hardware Chip Select to be used for all channels to minimize wiring connections.  
Feedback Clock Select  
10  
Allows the user to select the optional Feedback clock. The Feedback clock signal is used to eliminate propagation  
delays due to long cable lengths.  
CRC Setting  
11  
Allows the user to generate a CRC (Cyclic Redundancy Check). The CRC is located within the status word. The CRC  
SPI Output Format  
is only valid when the status byte is at the end of the serial word (see  
fringes (18 bits) are read.  
above) and the wholw  
Note: The polynomial used for CRC calculation is 10011. The resulting checksum is 4 bits and performed on the 28  
bits position word only, the status bits are not used in the CRC calcualtion.  
Warning: Changing configuration settings while in closed loop control is not recommended.  
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Display Setting  
Dual Axis Software Display Settings  
The Status Display in the center  
of the screen gives the user a  
snapshot of the interpolator con-  
figuration as well as Index posi-  
tion indication. The indicator  
light on the SmartPrecision soft-  
ware mimics the LED on the  
M3000SiDAA. The indicator will  
be green as long as the encoder  
is within the index window.  
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Calibration - SmartPrecision Software  
Confirm Calibration screen  
Calibration should be performed only after each of the encoders is aligned properly.  
Calibration can be initiated by either the Calibrate button using Smart Signal Software or through the recessed push  
button switch in the M3000SiDAA.  
To calibrate Channel 1:  
Through Software: Select "CALIBRATE SIGNAL on INPUT CHANNEL 1"  
Through Hardware: Push the recessed button once.  
The power indication for Channel 1 will rapidly blink until the calibration routine is complete.  
To calibrate Channel 2:  
Through Software: Select "CALIBRATE SIGNAL on INPUT CHANNEL 1"  
Through Hardware: Push the recessed button twice quickly (within 3 sec).  
The power indication for Channel 2 will rapidly blink until the calibration routine is complete.  
Warning: Changing configuration settings while in closed loop control is not recommended.  
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Calibrate - SmartPrecision Software  
Encoder Signal Data Plot showing pre-porcessed and processed data.  
The Encoder Signal Graph will plot the encoder signal for Channel 1 or Channel 2. The M3000SiDAA has a USB  
interface which allows very fast data collection and plotting. The number of data points to be plotted on the graph  
at one time can be changed using the "Plot Settings" button.  
The processed (Green) and/or the pre-processed (Red) signals can be shown on the graph. Plotted data can be  
saved using the "Save Data" button.  
Note:  
The calibration routine cannot be initiated through hardware (recessed push button) while the software is in the  
Encoder Signal Screen.  
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System Specifications  
Operating and Electrical Specifications  
Maximum Power Supply: 5V+/-5% @ 550mA (including two sensors)  
Operating Temperature: 0 to 70 degrees C  
Storage Temperature:  
Humidity:  
-30 to 80 degrees C  
10 to 90% RH non-condensing  
M3000SiDAA Output Connector  
Pinout (DB25 )  
PIN Function  
Pin 1  
Pin 13  
1
2
3
4
5
6
7
8
9
Serial Data Output 1+  
Serial Data Output 1-  
Chip Select Input 1+  
Chip Select Input 1-  
Serial Clock Input 1+  
Serial Clock Input 1-  
Serial Data Output 2+  
Serial Data Output 2-  
Chip Select Input 2+  
Pin 25  
M3000SiDAA Male DB25 Connector  
Front View  
Pin 14  
10 Chip Select Input 2-  
11 Serial Clock Input 2+  
12 Serial Clock Input 2-  
13 Serial Data Output 3+  
14 Serial Data Output 3-  
15 Chip Select Input 3+  
16 Chip Select Input 3-  
17 Serial Clock Input 3+  
18 Serial Clock Input 3-  
Serial Feedback Clock  
Output or Trigger input+  
19  
Serial Feedback Clock  
Output or Trigger input-  
20  
21 Do not connect  
22 Do not connect  
23 Alarm Output  
24 5volt power  
25 Ground  
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Serial Output Specification  
The interface to the M3000SiDAA Interpolator uses the following signals to implement serial communication, n_spiEnable  
(n_CS), spiDataOut (SDO), spiClockIn (SCK), and optionally spiClockOut (SCF). Each signal is differential and RS-422 compatible.  
See table for interpolator signal names, pin names, and pin locations  
I/O  
Interpolator  
Referenced  
Input  
15 Pin HD  
Connector  
Signal Name  
n_spiEnable  
Pin Name  
n_CS+  
n_CS-  
SCK+  
SCK-  
Function  
Chip Select+  
Pin Number  
7
8
14  
15  
5
4
10  
9
Chip Select-  
Input  
spiClockIn  
spiDataOut  
spiClockOut  
Serial Clock+  
Serial Clock-  
Serial Data Output+  
Serial Data Output-  
Input  
Input  
Output  
Output  
SDO+  
SDO-  
SCF+  
SCF-  
Serial Clock Feedback+ Output  
Serial Clock Feedback- Output  
Revision pending.  
Operational Modes: Standard Communication Mode  
The falling edge of the n_spiEnable signal loads the current data word into the output buffer. The serial data (MSB) is valid  
80ns (typical) after the falling edge of n_spiEnable signal. The n_spiEnable signal is kept asserted while spiClock signal shifts  
out the rest of the data bits. Each serial data bit is valid on the falling edge of the spiClock signal. The n_spiEnable should  
return to High after the last serial data bit has been shifted out  
Communication Mode Timing  
tCS  
n_spiEnable  
tCSC  
tCSD  
tCCS  
tspiL  
tV  
tspiH  
Clk1  
spiClocK  
Clk36  
spiDataOut  
MSB  
LSB  
Page 21  
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Serial Output Specification  
Symbol  
tspiH  
tspiL  
tCSC  
tCSD  
tV  
Parameter  
Minimum  
Typical  
Maximum Units  
spiClock High Time  
50  
50  
0
ns  
ns  
ns  
ns  
ns  
ns  
ns  
spiClock Low Time  
n_spiEnable to spiClock  
n_spiEnable to DataValid  
spiClock to Data Valid  
spiClock to n_spiEnable  
n_spiEnable High  
80  
80  
tCCS  
tCS  
0
50  
All timing are specified assuming no propagation delay from user's electronics and cabling.  
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Operational Modes: Trigger Approach Timing Diagram  
The Trigger Approach can be used in applications where synchronization of the position data to an event is required. Often, this  
mode is used when a fixed latency between a clock signal and the sampled position data is required. The customer can choose  
this mode of operation by using the optional SmartPrecision Software. In this mode, triggering is controlled by the n_spiEnable  
signal.  
The falling edge of n_spiEnable signal starts the process by immediately resetting the internal calculators and acquiring the latest  
A/D converter information. Old data in the calculation chain is discarded and the initiation of a new position calculation is started.  
The new data is ready in 1420ns. The n_spiEnable signal for retrieving the data must be asserted within 210ns after the new data  
is ready or the triggered acquisition will be over written by new data.  
Shifting the data out of the interpolator's serial port is accomplished exactly as in the Standard Communication mode of operation.  
In order to sample the next position, n_spiEnable must be brought high and then reasserted. See the Trigger Approach timing dia-  
gram below.  
Trigger Approach Timing Diagram  
tW  
tCS  
n_spiEnable  
tTDR  
tCCS  
tCSC  
tCSD  
tspiH  
Clk1  
tspiL  
Clk36  
spiClock  
spiDataOut  
tV  
LSB  
MSB  
Trigger Approach Timing Diagram  
Symbol  
Parameter  
Minimum  
Typical  
Maximum Units  
tspiH  
tspiL  
spiClock High Time  
spiClock Low Time  
50  
50  
ns  
ns  
tTDR n_spiEndable to DataReady 1420  
1600  
ns  
ns  
tW  
tCSC  
tCSD  
tV  
tCCS  
tCS  
n_spiEnable Low for trigger  
n_spiEnable to spiClock  
n_spiEnable to DataValid  
spiClock to Data Valid  
spiClock to n_spiEnable  
n_spiEnable High  
50  
0
80  
80  
ns  
ns  
ns  
ns  
0
50  
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Serial Output Specification  
Serial Data Format  
8bit status  
format 0  
28bit Position Word  
format 0  
7 6 5 4 3 2 1 0  
3 3 3 3 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1 9 8 7 6 5 4 3 2 1 0  
5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0  
28 bit Position Word  
format 1  
7 6 5 4 3 2 1 0  
8bit status  
format 1  
Troubleshooting  
Problem  
The Power/Calibration indicator will not come on.  
Solution  
• Make sure that the SmartPrecision electronics’ 25-pin HD connector is fully seated and connected.  
• Confirm that +5 Volts DC is being applied to pin 24 on the SmartPrecision electronics’ 25-pin HD connector and that pin 25 is connected to ground.  
Problem  
None of the SmartPrecision electronics’ LEDs turn on.  
Solution  
• Refer to the Grounding Reference Guide on pg. 9.  
Problem  
Can't get the SmartPrecision electronics’ "Signal" LEDs better than red or yellow; or the green, “ Proper Alignment” indicators  
don't stay illuminated over the full length of the scale.  
Solution  
• Verify that each sensor head has been aligned to the scale and that the mounting screws are tight. Check the dimensions for the  
mechanical mounting holes (and clamps if any) to make sure that each sensor is correctly located over the scale. Refer to the appropriate  
interface drawing.  
• Check that each scale is firmly mounted and can't jiggle or move in other than the intended direction.  
• Make sure that each scale is clean over its entire length or circumference.  
Problem  
The green Power/Calibration indicator is flashing unexpectedly.  
Solution  
• Part of the normal setup procedure is to activate the SmartPrecision electronics’ index capture process by pressing the recessed button on the  
SmartPrecision electronics’ connector body, once for sensor 1 and twice for sensor 2. Each Power/Calibration LED will begin to flash until the  
index mark on the scale passes under each sensor at least one time.  
Problem  
Can't complete the Capture Index process - the green Power/Calibration indicators don't stop flashing.  
Solution  
• Verify that each sensor is mounted in the correct orientation to the scale for the desired index mark. Refer to the interface drawing.  
• Refer to step 5 of the installation procedure to insure proper operation.  
Page 24  
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Cleaning scales  
General Particle Removal  
Blow off the contamination with nitrogen, clean air,  
or a similar gas.  
Contamination Removal  
Use a lint-free cleanroom wipe  
or cotton swab dampened with  
isopropyl alcohol or acetone only.  
Handle the scale by the edges.  
Do not scrub the scale.  
Contact MicroE Systems  
Thank you for purchasing a MicroE Systems product. You should expect  
the highest level of quality and support from MicroE. If you want to  
download the Mercury Encoder Installation Manual, Data Sheet or  
Mercury Encoders button.  
World Headquarters: 125 Middlesex Turnpike • Bedford • MA 01730 USA  
© 2008 MicroE Systems  
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