Lab CIEDE2000
Reference data 93.99/-0.50/-1.43 0.00 (as reference)
Dtp41a-xrite 94.03/-0.47/-1.44 0.04
Dtp41b-xrite 93.95/-0.51/-1.40 0.04
Dtp41c-xrite 94.04/-0.49/-1.42 0.04
Dtp41d-xrite 94.03/-0.48/-1.42 0.04
Dtp41a-xrga 94.02/-0.58/-1.56 0.17
Dtp41b-xrga 93.94/-0.62/-1.52 0.19
Dtp41c-xrga 94.04/-0.60/-1.54 0.18
Dtp41d-xrga 94.03/-0.59/-1.54 0.17
938-xrga 93.58/-0.62/-1.18 0.39
938-xrite 93.58/-0.52/-1.06 0.43
938-cp154 93.65/-0.53/-1.07 0.40
I1pro-xrga 93.87/-0.72/-1.35 0.33
I1pro-xrite 93.88/-0.61/-1.24 0.25
I1pro-cp154 93.99/-0.75/-1.37 0.36 == -GretagMacbeth
Notes:
1) Reference data: calibration strip white reference from x-rite.
2) -cp154: data measured with Colorport 1.5.4
3) -cp20: unspecified data were measured with ColorPort 2.0
-xrga: output with option xrga
-xrite: output with option x-rite
4) All 4 dtp41s were married with the same reference data
5) Reference strip was certified on 05-Jun-2010.
Tuesday, December 7, 2010
Saturday, December 4, 2010
Comparing an aged cal_strip with a new cal_strip
--- Aged cal_strip --- New cal_strip
It is not surprising to observe that ΔE2000 difference for the White Reference between the aged and new calibration strips is higher than 2.
How to examine a dtp41's Calibration Strip?
Required software and accessories:
a) Install ColorPort. The latest version is 2.0.5 , can be downloaded [ here ].
b) You need a software tool that can compare spectrum data, e.g. PatchTool from babelColor
c) Though not essential, preferably to have a alternative spectrometer such as i1pro.
Step 1: Install ColorPort
Step 2: Create a strip definition template for reading the calibration strip.
[ download ] 025.DTP41_cal-for_calibration_strip.xml
DTP41_calibration-strip.tab
For windows xp3, the file 025.DTP41_cal-for_calibration_strip.xml is to be copied to the installed directory C:\Program Files\X-rite\ColorPort 2.0\Resources\configurations\PatchTemplate.
Whereas DTP41_calibration-strip.tab is to be copied to the following folder:
C:\Documents and Settings\login_user_name\My Documents\ColorPort_Resources\custom\rgb
where ColorPort_Resources\custom\rgb is in My documents folder.
Step3: Start up ColorPort and create the custom calibration target
Now select the Measurement device and Patch Set as shown. If they are unavailable for selection, check that the 2 downloaded files are setup correctly. Next, select A4 size and proceed to create a template for reading in the strip. Save the target with the default name and by default it will be saved in tiff format.
Step 4: Reading the Calibration Strip
Click on the measurement tab, select the saved target and connect to dtp41.
Calibrate the instrument as per usual.
After calibration, feed the calibration strip again and press the button on the dtp41 to read the strip data.
Saved the data in either in cgats or pm5, both formats can be read by PatchTool.
Repeat the above if you want to read the strip data with i1pro. Select Patch mode ....
Step 5: Proceed to compare the collected strip data with PatchTool.
Comparing an aged cal_strip with a new cal_strip
a) Install ColorPort. The latest version is 2.0.5 , can be downloaded [ here ].
b) You need a software tool that can compare spectrum data, e.g. PatchTool from babelColor
c) Though not essential, preferably to have a alternative spectrometer such as i1pro.
Step 1: Install ColorPort
Step 2: Create a strip definition template for reading the calibration strip.
[ download ] 025.DTP41_cal-for_calibration_strip.xml
DTP41_calibration-strip.tab
For windows xp3, the file 025.DTP41_cal-for_calibration_strip.xml is to be copied to the installed directory C:\Program Files\X-rite\ColorPort 2.0\Resources\configurations\PatchTemplate.
Whereas DTP41_calibration-strip.tab is to be copied to the following folder:
C:\Documents and Settings\login_user_name\My Documents\ColorPort_Resources\custom\rgb
where ColorPort_Resources\custom\rgb is in My documents folder.
Step 4: Reading the Calibration Strip
Click on the measurement tab, select the saved target and connect to dtp41.
Calibrate the instrument as per usual.
After calibration, feed the calibration strip again and press the button on the dtp41 to read the strip data.
Saved the data in either in cgats or pm5, both formats can be read by PatchTool.
Repeat the above if you want to read the strip data with i1pro. Select Patch mode ....
Step 5: Proceed to compare the collected strip data with PatchTool.
Comparing an aged cal_strip with a new cal_strip
Saturday, November 27, 2010
Fine tune ColorPort 2.0 installation in Windows XP3
1) Windows crashes when it is trying to run xritelegacyd.exe during booting up
This file could be safely opted out with any registry editor that can modify the start-up menu.
2) To disable detection of i1isi deive that is unavailable in your system
Go to C:\Program Files\X-rite\Devices\Services and rename the folder i1ISIS to i1ISISxxx.
3) To release i1 device for other applications
Go to X-Rite Device Services in control panel, disconnect the required i1 device.
This file could be safely opted out with any registry editor that can modify the start-up menu.
2) To disable detection of i1isi deive that is unavailable in your system
Go to C:\Program Files\X-rite\Devices\Services and rename the folder i1ISIS to i1ISISxxx.
Go to X-Rite Device Services in control panel, disconnect the required i1 device.
Friday, November 26, 2010
120-patch Layout -- 6"x4" (4R size)
Optimal Layout for 6"x4" size
120 patches could be placed in a single 4R photo paper with the following configuration, unit used is mm.
DefaultPatchWidth="11"
DefaultPatchHeight="7"
120 patches could be placed in a single 4R photo paper with the following configuration, unit used is mm.
DefaultPatchWidth="11"
DefaultPatchHeight="7"
DefaultGapWidth=".1"
DefaultGapHeight="2"
DefaultHeaderLength="5"
DefaultTrailerLength="3"
DefaultTrailerLength="3"
Sunday, November 21, 2010
Monaco Profiler 1728-Patch Layout - A4 size
Monaco 1728 targets in 4x A4
DefaultPatchWidth="10" DefaultPatchHeight="7.5"
DefaultGapWidth=".25"
DefaultGapHeight="1.25"
DefaultHeaderLength="32.4"
DefaultTrailerLength="32.4"
Saturday, November 20, 2010
Practical Patch Layout Example - 468-patch
Optimal Layout for A4 size
468 patches could be placed in a single A4 paper with the following configuration, unit used is mm.
DefaultPatchWidth="10"
DefaultPatchHeight="7.25"
DefaultGapWidth="0.1"
DefaultGapHeight="1"
DefaultHeaderLength="32.5" (Black starter patch to edge-of-paper = 38mm)
DefaultTrailerLength="20.0"
468 patches could be placed in a single A4 paper with the following configuration, unit used is mm.
DefaultPatchWidth="10"
DefaultPatchHeight="7.25"
DefaultGapWidth="0.1"
DefaultGapHeight="1"
DefaultHeaderLength="32.5" (Black starter patch to edge-of-paper = 38mm)
DefaultTrailerLength="20.0"
Wednesday, November 17, 2010
Firmware Updates
To update your instrument’s firmware, follow these steps:
1. Connect your DTP41 to a serial port on your Macintosh or Windows machine.
2. Run the X-Rite® ToolCrib application located in the Misc Tools folder and select the appropriate serial port.
3. Select Firmware Loader from the Tools menu.
4. Click Select File. From the Open File dialog, choose the “.s19” file contained in this directory.
5. Click Load to begin the update. DO NOT attempt to do anything else with your PC while the firmware is loading. Some applications can interrupt the load process causing the update to fail.
6. Calibrate your instrument.
Update is unsuccessful...
If the firmware download failed and your instrument’s LED is green, your instrument is OK.
This means that the failure occurred before the update started or after it was finished. If your instrument’s LED is red, you must attempt the update again, without unplugging the instrument, just restart the application.
DO NOT unplug the instrument when the red LED is on . The LED will turn green when complete.
Latest firmware versions
1) DTP41 series I: dtp41vD421.s19 (firmware dated 2004-04-21)
2) DTP41 series II: dtp41vD422.s19 (firmware dated 2004-04-22)
[ download ] This Link was renewed on 2015-05-22
Left: DTP41 series II Right: DTP41 |
ToolCrib for Windows & Mac OSX, version: 5.0.14, released date: 2007-02-07
PC version
Mac version
Monday, November 15, 2010
Last Partial Column Won't Measure
Last Partial Column Won't Measure in Profiler or ColorPort
It happens when the last column is incompletely filled.
Problem was encountered when reading the last column of patches with ColorPort and a DTP41. The symptom is that the DTP41 will stop pulling the strip through a couple inches past the last patch in the column. The instrument LED will flash green rapidly to signal an error and no data will be transferred to ColorPort software.
The error occurs because the instrument did not receive the updated strip definition for the last column. This can happen if the user starts to measure the last column before ColorPort has received all the data from the previous strip. Since the software is still receiving measurement data, it cannot tell the instrument that the next column is shorter than the previous ones.
The fix for this problem is to select one of the full length columns in the left pane of the ColorPort data capture window and then select the last column. This will prompt the software to transmit the updated strip definition to the DTP41 and the user will then be able to measure the last column. You may have to try a few times in order to read the partial column successfully. The same issue would occur with a DTP45.
It happens when the last column is incompletely filled.
Problem was encountered when reading the last column of patches with ColorPort and a DTP41. The symptom is that the DTP41 will stop pulling the strip through a couple inches past the last patch in the column. The instrument LED will flash green rapidly to signal an error and no data will be transferred to ColorPort software.
The error occurs because the instrument did not receive the updated strip definition for the last column. This can happen if the user starts to measure the last column before ColorPort has received all the data from the previous strip. Since the software is still receiving measurement data, it cannot tell the instrument that the next column is shorter than the previous ones.
The fix for this problem is to select one of the full length columns in the left pane of the ColorPort data capture window and then select the last column. This will prompt the software to transmit the updated strip definition to the DTP41 and the user will then be able to measure the last column. You may have to try a few times in order to read the partial column successfully. The same issue would occur with a DTP45.
Sunday, November 14, 2010
Resetting an X-rite DTP41
1) Method I : without software
There are two ways to do the resetting with this method.
POWER UP RESET
This procedure resets the instrument to it's power-up defaults as last set by either the factory, or a third party package of software.
Plug in the instrument.
Press and hold the black measure button until the LED glows RED.
Unplug the instrument from power.
Press and hold the black measure button.
While holding the button, plug the instrument back in. The light will turn RED.
Release the button. The light will turn green. The instrument is now returned to factory default settings.
There are two ways to do the resetting with this method.
POWER UP RESET
This procedure resets the instrument to it's power-up defaults as last set by either the factory, or a third party package of software.
Plug in the instrument.
Press and hold the black measure button until the LED glows RED.
Release the button.
Press the button again (This must be done within ten seconds of step 3, or the instrument will return to the ready to measure mode, without resetting).
FULL FACTORY RESET
This will reset the instrument to the default settings for both measurement modes and communications. Unplug the instrument from power.
Press and hold the black measure button.
While holding the button, plug the instrument back in. The light will turn RED.
Release the button. The light will turn green. The instrument is now returned to factory default settings.
Alternatively, the ToolCrib software allows the flexibility to perform a reset to its power up default state or return the device to its Factory Default status. Once the instrument is connected to the software simply click the desired reset options.
Saturday, November 13, 2010
Instrument LED Indicator
The LED indicates a variety of instrument operation conditions, such as calibration mode, and operation. Below is a complete list of all conditions reported by the LED.
• Solid Green Light—self test passed and instrument is ready for use with defined strip.
• Slow Flashing Green Light—strip reading in progress (strip being read).
• Fast Flashing Green Light—strip reading attempted but the wrong strip was inserted, or strip skewed during reading.
Calibration Mode (Yellow Light)
• Solid Yellow Light—instrument calibration was entered, ready to start calibration with next button press.
• Slow Flashing Yellow Light—instrument calibration in progress (strip being read).
• Solid Green Light after Yellow Light—instrument calibration was successful and instrument is ready for use.
• Fast Flashing Yellow Light—instrument calibration failed, re-read calibration strip. If error persists, clean instrument and calibration strip (see Section Three). If error still persists, contact your Service epresentative.
Error/Reset Mode (Red Light)
• Solid Red Light—and error was detected, the self test failed. Verify correct power supply is used. Turn power off, reapply power and see if condition is corrected; if not, contact Service Representative.
• Solid Green or Yellow changing to Red—an instrument reset is in progress. To initiate a reset, press and hold the button, the LED changes from Green or Yellow to Red. While the LED is Red, press button again (within 10 seconds). The LED changes to Green and the reset is performed, reinstating the factory defaults. If the second button press is not performed when the LED is Red, the instrument will time-out, causing the LED to change to Green and the reset to be aborted.
Friday, November 12, 2010
DTP41/T Will Not Calibrate
[link] Many people have been unable to calibrate the DTP41/T because the sliding block on the bottom of the instrument was not in the proper position. To be successfully calibrated the block must be positioned so that the transmission lamp is located below the instrument optics.
When looking at the bottom of the instrument you will see two slots which allow access to this block. The slot on the left is identified with the letters BL and an arrow pointing to the right, the slot on the right is identified with a T/W and an arrow pointing to he left. The block must be positioned so that the slot on the right is open, you should be able to clearly see the block in the left hand slot.
The block should be in this position for calibration no matter whether you are going to use the instrument for reflection readings or for transmission readings.
Above graphic shows the correct block position on the DTP41/T for calibration. Notice that the block can be seen through the left hand slot.
When looking at the bottom of the instrument you will see two slots which allow access to this block. The slot on the left is identified with the letters BL and an arrow pointing to the right, the slot on the right is identified with a T/W and an arrow pointing to he left. The block must be positioned so that the slot on the right is open, you should be able to clearly see the block in the left hand slot.
The block should be in this position for calibration no matter whether you are going to use the instrument for reflection readings or for transmission readings.
Above graphic shows the correct block position on the DTP41/T for calibration. Notice that the block can be seen through the left hand slot.
Problems Reading Strips
[link] If you are having problems with every row, it may be a Strip Definition issue. Print drivers can rescale an image, without you even knowing it. To verify this, measure your patches from the top of a single patch to the bottom of a single patch, in the scanning direction, in millimeters. Measure the dividers in millimeters in the scanning direction. Verify the number of patches in a single row. You may want to write these numbers down for reference later. In Toolcrib, try reading in a strip in the Terminal window by simply placing a target into the instrument and pushing the button on the top of the instrument. A successful read will show a [00] in the window after reading. If you are getting any other reading, such as [27], that would be an unsuccessful read. After reading in, if you are getting an unsuccessful read, go into the Setup window in Toolcrib and go to the Strip Definition tab. Look at the numbers listed in there for patch measurements, divider measurements and number of patches in a row. If the numbers don't match the numbers you measured earlier, this means your print driver is rescaling the image (shrinking or stretching it).
If you can read a different row, it may be a dividers issue. If any of the patches might be dark or light compared to the divider (close in density) between the patch above and below the dividers. The instrument's requirements are that there must be at least a 0.5 Density difference between the patch above, the divider and the patch below. If light or dark, you can fill them in with white correction fluid, or a black marker, depending on the issue. This should solve your problem.
If not reading any rows on any sheets, check the measurements of the lead edge of the sheet. It must be 1 ½ inches on the lead edge of the sheet to the top of the first patch.
If you can read a different row, it may be a dividers issue. If any of the patches might be dark or light compared to the divider (close in density) between the patch above and below the dividers. The instrument's requirements are that there must be at least a 0.5 Density difference between the patch above, the divider and the patch below. If light or dark, you can fill them in with white correction fluid, or a black marker, depending on the issue. This should solve your problem.
If not reading any rows on any sheets, check the measurements of the lead edge of the sheet. It must be 1 ½ inches on the lead edge of the sheet to the top of the first patch.
Thursday, November 11, 2010
DTP41-100-KIT
DTP41 - "Lost Color Reflection Reference"
Although the Calibration Strips were matched up with the DTP41 units in production, they can be replaced in the field if lost or damaged. The part number for ordering a replacement kit is listed below.
DTP41-100-KIT inclues:
a) DTP41-100
b) Cal Reference Update & ToolCrib Disc
c) Update Instructions
Re-certification [link]
It has been suggested by x-rite that the device is to be inspected and re-certified after 12 months of actual use.
Do take note that the update calibration reference in ToolCrib does not actually marry the reference to the device. If the measurement difference is abnormally higher than some known reference patches, it may be time to send in the unit for factory re-certification.
White Reference
Followings were White Reference data collected with 4 certified dtp41s, results were also compared to x-rite 938 and i1pro.
Lab CIEDE2000
Reference data 93.99/-0.50/-1.43 0.00 (as comparison reference)
Dtp41a-xrite 94.03/-0.47/-1.44 0.04
Dtp41b-xrite 93.95/-0.51/-1.40 0.04
Dtp41c-xrite 94.04/-0.49/-1.42 0.04
Dtp41d-xrite 94.03/-0.48/-1.42 0.04
938-xrga 93.58/-0.62/-1.18 0.39
938-xrite 93.58/-0.52/-1.06 0.43
I1pro-xrga 93.87/-0.72/-1.35 0.33
I1pro-xrite 93.88/-0.61/-1.24 0.25
I1pro-cp154 93.99/-0.75/-1.37 0.36 == -GretagMacbeth
Where to order:
1) Colour Confidence DTP41 replacement calibration strip
2) http://www.cancomuk.com/ [link]
3) ISO-Colour
Although the Calibration Strips were matched up with the DTP41 units in production, they can be replaced in the field if lost or damaged. The part number for ordering a replacement kit is listed below.
DTP41-100-KIT inclues:
a) DTP41-100
b) Cal Reference Update & ToolCrib Disc
c) Update Instructions
Re-certification [link]
It has been suggested by x-rite that the device is to be inspected and re-certified after 12 months of actual use.
Do take note that the update calibration reference in ToolCrib does not actually marry the reference to the device. If the measurement difference is abnormally higher than some known reference patches, it may be time to send in the unit for factory re-certification.
White Reference
Followings were White Reference data collected with 4 certified dtp41s, results were also compared to x-rite 938 and i1pro.
Lab CIEDE2000
Reference data 93.99/-0.50/-1.43 0.00 (as comparison reference)
Dtp41a-xrite 94.03/-0.47/-1.44 0.04
Dtp41b-xrite 93.95/-0.51/-1.40 0.04
Dtp41c-xrite 94.04/-0.49/-1.42 0.04
Dtp41d-xrite 94.03/-0.48/-1.42 0.04
938-xrga 93.58/-0.62/-1.18 0.39
938-xrite 93.58/-0.52/-1.06 0.43
I1pro-xrga 93.87/-0.72/-1.35 0.33
I1pro-xrite 93.88/-0.61/-1.24 0.25
I1pro-cp154 93.99/-0.75/-1.37 0.36 == -GretagMacbeth
Where to order:
1) Colour Confidence DTP41 replacement calibration strip
2) http://www.cancomuk.com/ [link]
3) ISO-Colour
Wednesday, November 10, 2010
Calibrating DTP41
Calibrating the X-Rite DTP41
All spectrophotometers require periodic calibration to ensure accurate measurements. The DTP41 is designed to ask for calibration every 24hrs of power-up time. In addition, many software applications will require calibration at the start of the program. To manually force an instrument calibration proceed as follows:
Begin by locating the Color Reflection Reference (P/N DTP41-100). It is located in a protective envelope. This is a calibrated and certified media NOTE: Each reference for a DTP41 has a serial number, and is to be used only with the instrument it came with!
Apply power to the Spectrophotometer
Insert the calibration strip, so that the black and colored squares line up with the mark on the face of the instrument. Insert until it touches the back rollers, this is approximately three inches.
Push and hold the black button, until the light turns solid yellow; release the button.
Press the black button again (a second time). The instrument LED will begin to flash yellow. The motor starts, but the strip does not move - THIS IS NORMAL.
The LED will flash green and then begin to flash yellow again. In approximately one second the calibration reference should begin to be pulled through.
If calibration is performed successfully, the light will return to green. If the calibration failed, the light will begin flashing yellow rapidly. If the calibration fails, wait for the error to time out: try to calibrate again.
After a successful calibration - return the Color Reflection Reference strip to its protective envelope
All spectrophotometers require periodic calibration to ensure accurate measurements. The DTP41 is designed to ask for calibration every 24hrs of power-up time. In addition, many software applications will require calibration at the start of the program. To manually force an instrument calibration proceed as follows:
Begin by locating the Color Reflection Reference (P/N DTP41-100). It is located in a protective envelope. This is a calibrated and certified media NOTE: Each reference for a DTP41 has a serial number, and is to be used only with the instrument it came with!
Apply power to the Spectrophotometer
Insert the calibration strip, so that the black and colored squares line up with the mark on the face of the instrument. Insert until it touches the back rollers, this is approximately three inches.
Push and hold the black button, until the light turns solid yellow; release the button.
Press the black button again (a second time). The instrument LED will begin to flash yellow. The motor starts, but the strip does not move - THIS IS NORMAL.
The LED will flash green and then begin to flash yellow again. In approximately one second the calibration reference should begin to be pulled through.
If calibration is performed successfully, the light will return to green. If the calibration failed, the light will begin flashing yellow rapidly. If the calibration fails, wait for the error to time out: try to calibrate again.
After a successful calibration - return the Color Reflection Reference strip to its protective envelope
Monday, November 8, 2010
DTP41 Strip Definition
Strip definition & how to read a custom strip [x-rite link]
The DTP41 is an accurate, powerful, fast strip reading spectrophotometer. The only problem with such a powerful tool, is that users often find that they'd like to do more with it than can be done with the software they use with it every day. A frequent call to the applications desk is "how do I do X with my DTP41?" Below we will outline the basic steps to use to retrieve data from the DTP41 using the supplied ToolCrib software. To illustrate this we will use the calibration strip as the strip to read from. You can design your own strip if you want, following some simple guidelines also outlined below.
Designing the Strip
There are several elements in any successful strip design, all of which can be seen in the calibration reference supplied with the DTP41. The minimum recommended patch size is 7mm in the direction of travel and 13mm wide, this allows for easy positioning of the strip in the reader. Each patch is delineated by a gap, or divider which is .5D in shift from the patches on either side. The most common gap colors are thus white, 50% gray and black. While the minimum gap size is only .5mm it is strongly recommended that you use a larger gap, which allows for more variation in the printed output, here we use the standard recommended size of 2mm. The above elements seem relatively obvious, but their are two other pieces that are also important for a successful strip design: The leader and trailer. The leader is defined as the material before the first patch. The DTP41 requires a minimum of a 1.5 inch leader, with at least .5 inch of clean base before the first patch. The trailer length is defined as at least the width of two patches plus two separators. In the above design, the minimum trailer is then 7mm+2mm+7mm+2mm=18mm. This is very important almost every day we get a call from a distraught user who was a bit to tight with the scissors!
Minimum requirement
Patch size: 7mm x 13 mm
Divider: 0.5mm
Leader: 1.5 inch
Trailer: 15 mm
Defining the Strip
Just like you need a road map to know where you are, the DTP41 requires a "roadmap" of the strip you want it to read. This roadmap is the strip definition (the DS command) which consists of 5 distinct parts for a reflection strip and 6 parts for a transmission strip.
Looking at the chart above one can then see that the strip definition for the Calibration reference above is 0111000020008DS. If this were a transmission strip we would use the same definition with the addition of the trailer length 01107000200080016DS. But what do you do with this definition? Lets look at ToolCrib:
ToolCrib
ToolCrib is a utility program that ships with every DTP41. There is a version for the Windows platform and the Macintosh platform. This contains a simple setup tool, as well as a dedicated terminal (communications) window. When you first start ToolCrib you will be asked to select the instrument and serial port. After a successful connection you are presented with a blank window. Go to the menu bar and Select Tools>Setup. The Setup window is divided into two sections: The left window is dynamic and allows you to set certain parameters of your instrument. Most likely the only two things you will want to change here will be data type, and whether you are reading in reflective or transmission mode. The Right window reveals certain things about your instrument including the firmware installed and the boot version of firmware. After setting the data type you want, you will once again use the Tools menu to select the Terminal tool.
The Terminal tool is where we send commands to the instrument and it sends back data along with status codes that allow it to speak to you. This is the window where we will enter our strip definition. Before we do this, lets verify that the instrument is talking correctly, and contains no errors. Type: sv [return] This should return the instrument type and the firmware followed by a <00> "I'm okay" status code. Any other code should be cleared with the xe [return] command. This will list all errors and clear them. Now use the the strip definition from above: 0111000020008DS [return]. You might also want to set a configuration switch to auto-transmit the data after you read a strip. This can be done using the 0105cf [return] switch.
Let's Try it!
After selecting the data type you want in the Setup menu and entering your strip definition in the Terminal window you are ready to read the strip! With the terminal window insert the cal reference until it hits the back rollers, centering the patches under the two lines on the front of the DTP41. Push the black pushbutton. After a second or so the strip should be pulled through the instrument. Assuming that the light returned directly to green, you should see data in the terminal window if you used the 0105cf [return] switch. If you didn't turn auto-transmit on, use the ts [return] command to transmit the strip data. Now try it with your own strip, just make sure you follow the rules stated above and you can easily read any DTP41 compatible strip into ToolCrib.
The DTP41 is an accurate, powerful, fast strip reading spectrophotometer. The only problem with such a powerful tool, is that users often find that they'd like to do more with it than can be done with the software they use with it every day. A frequent call to the applications desk is "how do I do X with my DTP41?" Below we will outline the basic steps to use to retrieve data from the DTP41 using the supplied ToolCrib software. To illustrate this we will use the calibration strip as the strip to read from. You can design your own strip if you want, following some simple guidelines also outlined below.
Designing the Strip
There are several elements in any successful strip design, all of which can be seen in the calibration reference supplied with the DTP41. The minimum recommended patch size is 7mm in the direction of travel and 13mm wide, this allows for easy positioning of the strip in the reader. Each patch is delineated by a gap, or divider which is .5D in shift from the patches on either side. The most common gap colors are thus white, 50% gray and black. While the minimum gap size is only .5mm it is strongly recommended that you use a larger gap, which allows for more variation in the printed output, here we use the standard recommended size of 2mm. The above elements seem relatively obvious, but their are two other pieces that are also important for a successful strip design: The leader and trailer. The leader is defined as the material before the first patch. The DTP41 requires a minimum of a 1.5 inch leader, with at least .5 inch of clean base before the first patch. The trailer length is defined as at least the width of two patches plus two separators. In the above design, the minimum trailer is then 7mm+2mm+7mm+2mm=18mm. This is very important almost every day we get a call from a distraught user who was a bit to tight with the scissors!
Minimum requirement
Patch size: 7mm x 13 mm
Divider: 0.5mm
Leader: 1.5 inch
Trailer: 15 mm
Defining the Strip
Just like you need a road map to know where you are, the DTP41 requires a "roadmap" of the strip you want it to read. This roadmap is the strip definition (the DS command) which consists of 5 distinct parts for a reflection strip and 6 parts for a transmission strip.
Looking at the chart above one can then see that the strip definition for the Calibration reference above is 0111000020008DS. If this were a transmission strip we would use the same definition with the addition of the trailer length 01107000200080016DS. But what do you do with this definition? Lets look at ToolCrib:
ToolCrib
ToolCrib is a utility program that ships with every DTP41. There is a version for the Windows platform and the Macintosh platform. This contains a simple setup tool, as well as a dedicated terminal (communications) window. When you first start ToolCrib you will be asked to select the instrument and serial port. After a successful connection you are presented with a blank window. Go to the menu bar and Select Tools>Setup. The Setup window is divided into two sections: The left window is dynamic and allows you to set certain parameters of your instrument. Most likely the only two things you will want to change here will be data type, and whether you are reading in reflective or transmission mode. The Right window reveals certain things about your instrument including the firmware installed and the boot version of firmware. After setting the data type you want, you will once again use the Tools menu to select the Terminal tool.
The Terminal tool is where we send commands to the instrument and it sends back data along with status codes that allow it to speak to you. This is the window where we will enter our strip definition. Before we do this, lets verify that the instrument is talking correctly, and contains no errors. Type: sv [return] This should return the instrument type and the firmware followed by a <00> "I'm okay" status code. Any other code should be cleared with the xe [return] command. This will list all errors and clear them. Now use the the strip definition from above: 0111000020008DS [return]. You might also want to set a configuration switch to auto-transmit the data after you read a strip. This can be done using the 0105cf [return] switch.
Let's Try it!
After selecting the data type you want in the Setup menu and entering your strip definition in the Terminal window you are ready to read the strip! With the terminal window insert the cal reference until it hits the back rollers, centering the patches under the two lines on the front of the DTP41. Push the black pushbutton. After a second or so the strip should be pulled through the instrument. Assuming that the light returned directly to green, you should see data in the terminal window if you used the 0105cf [return] switch. If you didn't turn auto-transmit on, use the ts [return] command to transmit the strip data. Now try it with your own strip, just make sure you follow the rules stated above and you can easily read any DTP41 compatible strip into ToolCrib.
Sunday, November 7, 2010
Configuration Commands for DTP41
Configuration settings:
The convention used for configuration settings is: switch setting, switch, CF -return- (with no comma separators). All settings that are denoted with an asterisk* are factory default of the instrument. Commands are case insensitive.
Syntax: **##cf
where ** is the switch setting or option selection
## is the switch or index to the item to be configured
Examples
0105CF <return> would turn autotransmit on
040ACF <return> would set output precision to 4 decimal places.
Switch Name and Switch Setting
00 Language
00 - English*
01 Beeper Tone
00 - off
01 - soft
02 - medium
03 - loud*
04 RS232 Handshaking
00 - off*
01 - cts
02 - busy
03 - xon
05 Auto transmit
00 - off*
01 - on
06 Decimal point
00 - off
01 - on*
07 Response data separator modes
00- space
01 - comma*
02 - tab
03 - carriage return
04 - carriage return & line feed
05 - line feed
08 Response delimiter in RCI mode (see 12CF)
00 - carriage return
01 - carriage return & line feed*
02 - line feed
09 Echo settings
00 - off*
01 - on
0A Decimal Precision
00 - .
01 - .0
02 - .00*
03 - .000
04 - .0000
05 - .00000
0C Min/Max mode
00 - off*
01 - on
0D Persistent error
00 - off*
01 - on
0F Show data labels
00 - off*
01 - on
10 Emulation mode
00 - factory default (???)
11 Drive motor calibration at power up
00 - off*
01 - on
12 RS-232 Protocol modes
00 - RCI*
01 - ICP
13 Measurement modes
00 - Static measurement mode
01 - Dynamic measurement mode*
14 Number of samples to average per static reading
0x01*
.
.
0xff
15 Number of readings taken in static measurement
0x01*
.
.
0xff
16 Illuminant/Observer types
00 - A_2
01 - A_10
02 - C_2
03 - C10
04 - D50_2*
05 - D50_10
06 - D65_2
07 - D65_10
08 - F2_2
09 - F2_10
0A - F7_2
0B - F7_10
0C - F11_2
0D - F11_10
0E - F12_2
0F - F12_10
-------------
10 - D75_2 (added after firmware v8212)
11 - D75_10 (added after firmware v8212)
12 - D55_2 (added after firmware v8212)
13- D55_10 (added after firmware v8212)
17 Density status types
00 - Status_A
01 - Status_E
02 - Status_I
03 - Status_T*
04 - Spectral
------------
05 - Spectral_X (added after firmware v8212)
06 - Status_HIFI (VCMYRGBO) (added after firmware v8212)
08 - Status_Tx (added after firmware v8212)
09 - Status_Ax (reflectance) (added after firmware v8212)
0A - Status_Ex (added after firmware v8212)
0B - Status_G (added after firmware v8212)
0C - Status_M (added after firmware v8212)
0D - Status_Axt (transmission) (added after firmware v8212)
0E - Status_Mx (added after firmware v8212)
Note: Status responses with the sub-x option are responses with correction factors entered to more closely match the existing population of filtered densitometers. Status responses without the sub-x option correspond directly to the ANSI definitions.
18 Data Output types
00 - Density
01 - Plus Dot
02 - Minus Dot
03 - Reflectance*
04 - Lab
05 - XYZ
06 - Yxy
07 - xyY
08 - LCh
09 - Density (VCMYRGBO)
19 Instrument mode (added after firmware v8212)
00 - Reflectance*
01 - Transmission
1E Reflect calibration timeout
18 - set it to 24 hours
1F Trailer timout
02 - set it to 2 seconds
20 Transmission calibration timeout
18 - set it to 24 hours
21 unknown
00
01*
22 unknown
00
01*
Operation Commands
CM Calibrate Drive motor
CR Calibrate Reflectance
This executes reflection calibration using the supplied calibration reference
CU Calibrate Unit (added after firmware v8212)
This enters the CR, CM and, if transmission mode is present CT
DM Drive Motor - turns on/off the drive motor
02 DM returns current motor speed
1.20DM will set the motor to the default motor speed
RI Reset Instrument to its power - up state
RM Request Measurement Initiates the measurement process
SV or V Send Version returns the model and firmware version
XE Clear and transmit errors
Undocumented Commands
note: use it at own risk as they may affect normal operation of dtp41
CE Clear errors in the error memory stack
CL unconfirmed (calibration learn mode: test white reference???)
CT Transmission calibration for dtp41t only [ Link ]
00CT white calibration
01CT black calibration
00SN return the instrument serial number
04SN return calibration strip serial number
05SN return 000000
00CR static calibration Black reference, to be confirmed
01CR static calibration White reference, to be confirmed
00DS or DS return 0300700005008
01DS return 0070700010080023
BR return present baud rate
MP ???
00PB disable keypress switch
01PB enable keypress switch
Error Codes
All errors are displayed in a <xx> format where the xx is equivalent to two numbers, or a number followed by a letter. If instead the error comes back like <Ax> (capitol letter followed by a number) this indicates a compound error. Use the XE command to list the individual errors and clear the error stack.
00 = NO ERROR
01 = MEASUREMENT STATUS -Measurement complete
02 = CALIBRATION STATUS -Calibration complete
03 = KEYPRESSED STATUS -A Key was pressed
04 = DEFAULTS LOADED STATUS
11 = BAD COMMAND -Command is unrecognized
12 = BAD PARAMETERS -One or more parameters missing or too many parameters given
13 = PRM RANGE ERROR -One or more of the parameters is out of range
14 = BUSY -Instrument is currently busy command ignored
15 = USER ABORT ERROR
20 = MEASUREMENT ERROR -General measurement error
21 = TIMEOUT
22 = BAD STRIP
23 = BAD COLOR
24 = BAD STEP
25 = BAD PASS
26 = BAD PATCHES
27 = BAD READING
28 = NEEDS CAL ERROR -Instrument requires a new calibration error
29 = CAL FAILURE ERROR -Calibration failed
30 = INSTRUMENT ERROR -General internal instrument error
31 = LAMP ERROR
32 = FILTER ERROR
33 = FILTER MOTOR ERROR
34 = DRIVE MOTOR ERROR
35 = KEYPAD ERROR
36 = DISPLAY ERROR
37 = MEMORY ERROR
38 = ADC ERROR
39 = PROCESSOR ERROR
3C = INPUT POWER ERROR
3D = TEMPERATURE ERROR
3F = TRANSMISSION LAMP ERROR
About DTP41T [ Link ]
The convention used for configuration settings is: switch setting, switch, CF -return- (with no comma separators). All settings that are denoted with an asterisk* are factory default of the instrument. Commands are case insensitive.
Syntax: **##cf
where ** is the switch setting or option selection
## is the switch or index to the item to be configured
Examples
0105CF <return> would turn autotransmit on
040ACF <return> would set output precision to 4 decimal places.
Switch Name and Switch Setting
00 Language
00 - English*
01 Beeper Tone
00 - off
01 - soft
02 - medium
03 - loud*
04 RS232 Handshaking
00 - off*
01 - cts
02 - busy
03 - xon
05 Auto transmit
00 - off*
01 - on
06 Decimal point
00 - off
01 - on*
07 Response data separator modes
00- space
01 - comma*
02 - tab
03 - carriage return
04 - carriage return & line feed
05 - line feed
08 Response delimiter in RCI mode (see 12CF)
00 - carriage return
01 - carriage return & line feed*
02 - line feed
09 Echo settings
00 - off*
01 - on
0A Decimal Precision
00 - .
01 - .0
02 - .00*
03 - .000
04 - .0000
05 - .00000
0C Min/Max mode
00 - off*
01 - on
0D Persistent error
00 - off*
01 - on
0F Show data labels
00 - off*
01 - on
10 Emulation mode
00 - factory default (???)
11 Drive motor calibration at power up
00 - off*
01 - on
12 RS-232 Protocol modes
00 - RCI*
01 - ICP
13 Measurement modes
00 - Static measurement mode
01 - Dynamic measurement mode*
14 Number of samples to average per static reading
0x01*
.
.
0xff
15 Number of readings taken in static measurement
0x01*
.
.
0xff
16 Illuminant/Observer types
00 - A_2
01 - A_10
02 - C_2
03 - C10
04 - D50_2*
05 - D50_10
06 - D65_2
07 - D65_10
08 - F2_2
09 - F2_10
0A - F7_2
0B - F7_10
0C - F11_2
0D - F11_10
0E - F12_2
0F - F12_10
-------------
10 - D75_2 (added after firmware v8212)
11 - D75_10 (added after firmware v8212)
12 - D55_2 (added after firmware v8212)
13- D55_10 (added after firmware v8212)
17 Density status types
00 - Status_A
01 - Status_E
02 - Status_I
03 - Status_T*
04 - Spectral
------------
05 - Spectral_X (added after firmware v8212)
06 - Status_HIFI (VCMYRGBO) (added after firmware v8212)
08 - Status_Tx (added after firmware v8212)
09 - Status_Ax (reflectance) (added after firmware v8212)
0A - Status_Ex (added after firmware v8212)
0B - Status_G (added after firmware v8212)
0C - Status_M (added after firmware v8212)
0D - Status_Axt (transmission) (added after firmware v8212)
0E - Status_Mx (added after firmware v8212)
Note: Status responses with the sub-x option are responses with correction factors entered to more closely match the existing population of filtered densitometers. Status responses without the sub-x option correspond directly to the ANSI definitions.
18 Data Output types
00 - Density
01 - Plus Dot
02 - Minus Dot
03 - Reflectance*
04 - Lab
05 - XYZ
06 - Yxy
07 - xyY
08 - LCh
09 - Density (VCMYRGBO)
19 Instrument mode (added after firmware v8212)
00 - Reflectance*
01 - Transmission
1E Reflect calibration timeout
18 - set it to 24 hours
1F Trailer timout
02 - set it to 2 seconds
20 Transmission calibration timeout
18 - set it to 24 hours
21 unknown
00
01*
22 unknown
00
01*
Operation Commands
CM Calibrate Drive motor
CR Calibrate Reflectance
This executes reflection calibration using the supplied calibration reference
CU Calibrate Unit (added after firmware v8212)
This enters the CR, CM and, if transmission mode is present CT
DM Drive Motor - turns on/off the drive motor
02 DM returns current motor speed
1.20DM will set the motor to the default motor speed
RI Reset Instrument to its power - up state
RM Request Measurement Initiates the measurement process
SV or V Send Version returns the model and firmware version
XE Clear and transmit errors
Undocumented Commands
note: use it at own risk as they may affect normal operation of dtp41
CE Clear errors in the error memory stack
CL unconfirmed (calibration learn mode: test white reference???)
CT Transmission calibration for dtp41t only [ Link ]
00CT white calibration
01CT black calibration
00SN return the instrument serial number
04SN return calibration strip serial number
05SN return 000000
00CR static calibration Black reference, to be confirmed
01CR static calibration White reference, to be confirmed
00DS or DS return 0300700005008
01DS return 0070700010080023
BR return present baud rate
MP ???
00PB disable keypress switch
01PB enable keypress switch
Error Codes
All errors are displayed in a <xx> format where the xx is equivalent to two numbers, or a number followed by a letter. If instead the error comes back like <Ax> (capitol letter followed by a number) this indicates a compound error. Use the XE command to list the individual errors and clear the error stack.
00 = NO ERROR
01 = MEASUREMENT STATUS -Measurement complete
02 = CALIBRATION STATUS -Calibration complete
03 = KEYPRESSED STATUS -A Key was pressed
04 = DEFAULTS LOADED STATUS
11 = BAD COMMAND -Command is unrecognized
12 = BAD PARAMETERS -One or more parameters missing or too many parameters given
13 = PRM RANGE ERROR -One or more of the parameters is out of range
14 = BUSY -Instrument is currently busy command ignored
15 = USER ABORT ERROR
20 = MEASUREMENT ERROR -General measurement error
21 = TIMEOUT
22 = BAD STRIP
23 = BAD COLOR
24 = BAD STEP
25 = BAD PASS
26 = BAD PATCHES
27 = BAD READING
28 = NEEDS CAL ERROR -Instrument requires a new calibration error
29 = CAL FAILURE ERROR -Calibration failed
30 = INSTRUMENT ERROR -General internal instrument error
31 = LAMP ERROR
32 = FILTER ERROR
33 = FILTER MOTOR ERROR
34 = DRIVE MOTOR ERROR
35 = KEYPAD ERROR
36 = DISPLAY ERROR
37 = MEMORY ERROR
38 = ADC ERROR
39 = PROCESSOR ERROR
3C = INPUT POWER ERROR
3D = TEMPERATURE ERROR
3F = TRANSMISSION LAMP ERROR
About DTP41T [ Link ]
Saturday, November 6, 2010
Spot Reading
Step by step proceduce for spot read measurement:-
1) Start the ToolCrib software.
2) Select the DTP41 instrument and the serial port it is connected to.
3) Under the Tools menu select Setup.
4) Select the type of response (ie: Status T, Status E, Lab, etc.) you wish to use.
5) Close the Setup window.
6) Under the Tools menu select Terminal.
In the following series of commands <return> means to tuse your “return” key after each comand.
7) Type 0105cf <return> (This sets the instrument into auto transmit mode)
8) Type 0013cf <return> (this sets the instrument into static read mode.
9) Type 0214cf <return> (this sets the insturment to average two reads of the same spot)
10) Type 0115cf <return> (this will send back reading for the button push)
11) Type 030acf <return> (this will set three decimal place precision)
12) Cut out the template on page two, be careful to follow the instructions precisely.
13) Sandwich the the area to be read between the upper and lower sheets of paper.
14) Insert the template and sample into the instrument. This is most easily accomplished by slightly lifting the top of the instrument and sliding the template and sample in from the side.
15) Press the read button on the instrument, the selected response will appear in the terminal window.
DTP41 Static Reading Template [ download ]
1) Start the ToolCrib software.
2) Select the DTP41 instrument and the serial port it is connected to.
3) Under the Tools menu select Setup.
4) Select the type of response (ie: Status T, Status E, Lab, etc.) you wish to use.
5) Close the Setup window.
6) Under the Tools menu select Terminal.
In the following series of commands <return> means to tuse your “return” key after each comand.
7) Type 0105cf <return> (This sets the instrument into auto transmit mode)
8) Type 0013cf <return> (this sets the instrument into static read mode.
9) Type 0214cf <return> (this sets the insturment to average two reads of the same spot)
10) Type 0115cf <return> (this will send back reading for the button push)
11) Type 030acf <return> (this will set three decimal place precision)
12) Cut out the template on page two, be careful to follow the instructions precisely.
13) Sandwich the the area to be read between the upper and lower sheets of paper.
14) Insert the template and sample into the instrument. This is most easily accomplished by slightly lifting the top of the instrument and sliding the template and sample in from the side.
15) Press the read button on the instrument, the selected response will appear in the terminal window.
DTP41 Static Reading Template [ download ]
Friday, November 5, 2010
Specifications of DTP41
Fast, Affordable, Versatile, Accurate Measurement Solution
DTP41 is a strip reading spectrometer that measures color with spectral technology. Whether your need is for color calibration, color process control or color management, the DTP41 autoscan spectrophotometer gives precise color measurements.
The DTP41 offers a UV model to help deal with fluorescent paper brighteners commonly found in proofing papers. Reducing the fluorescent effect from the brighteners, the UV model will assure accurate color measurement on these media.The transmission model, DTP41T, offers dual reflection and transmission capability which is an extremely versatile tool for a variety of applications including photo transparencies, research and testing.
Specifications
Measuring Geometry
Reflection 45°/0° per ANSI/ISO 5-4 (IT2.17)
Transmission 180°/0° (DTP41/T model) per ANSI/ISO 5-2 (IT2.19)
Spot Size At Sample
1.8mm (.070 in) in scan direction x 2.5mm (.097 in) wide
Light Source
Gas Pressure @ 2850°K
Spectral Sensor
DRS Technology, 24 point engine, 31 point reporting
Spectral Range
400nm to 700nm
Illuminant Types
A, C, D50, D55, D65, D75, F2, F7, F11 & F12
Standard Observers
2° & 10°
Density Responses
Status T, E, I, & A (plus Status M on DTP41/T model)
Measurement Time
Approx. 0.25 sec/patch (7mm patch)
Reflection Measurement (DTP41 & DTP41/T)
Inter-Instrument Agreement
0.3 ÆE cmc avg. typical
(avg. based on 12 BCRA tiles)
Measurement Range
0.00D to 2.50D; 0 to 160% R (reflection)
Repeatability On White
0.2 ÆE max.; ±0.01D max
Linearity
± .01D or 1%
Transmission Measurement (DTP41/T)
Inter-Instrument Agreement
0.02D or 2% typical, 0 to 3.0D
Measurement Range
0.00D to 5.00D; 0 to 110% T (transmission)
Repeatability
± 0.01D or 1%, 0 to 3.5D (visual)
Media Thickness
0.08mm (0.003 in) to 0.6mm (.025 in) for optimum scanning
Maximum Length Of Sheet
1400mm (55 in) (scanning direction)
Measuring Location (From Edge)
Columns of patches must fall within 100mm (4 in)
insert-able area on standard model, and within 225mm (9 in)
insert-able area on DTP41W9 model. Built-in guide for 35mm film
Minimum Patch Dimensions
7.0mm (.28 in) high in scan direction
12mm (.47 in) width recommended
Patch Quantities
1 minimum, 100 maximum per pass
Recommended Leader Length
38mm (1.5 in)
Minimum Footer Length
Greater of 30mm or 2 patch + 2 gap heights
Data Interface
RS-232 serial interface with baud rates from 1200 to 57.6k
communication USB
Power Required
12v DC, Universal 100–240 VAC;
50–60 Hz adapter; 30W
Calibration
Calibration strips as needed
Environmental
+10° (50°F) to +40°C (104°F) operating
30% to 85% RH non condensing
Warm-up Time
None
Physical Dimensions
Height: 88mm (3.45 in)
Width: 184mm (7.25 in)
Depth: 114mm (4.5 in)
Weight
890g (1.96 lb), DTP41/T 1090g (2.40 lb)
Accessories Provided
Calibration Reference
Interface Cable: DB9 RS-232 and/or USB
AC Adapter
Link to x-rite for related information.
dtp41 pdf manual download
DTP41 is a strip reading spectrometer that measures color with spectral technology. Whether your need is for color calibration, color process control or color management, the DTP41 autoscan spectrophotometer gives precise color measurements.
The DTP41 offers a UV model to help deal with fluorescent paper brighteners commonly found in proofing papers. Reducing the fluorescent effect from the brighteners, the UV model will assure accurate color measurement on these media.The transmission model, DTP41T, offers dual reflection and transmission capability which is an extremely versatile tool for a variety of applications including photo transparencies, research and testing.
Specifications
Measuring Geometry
Reflection 45°/0° per ANSI/ISO 5-4 (IT2.17)
Transmission 180°/0° (DTP41/T model) per ANSI/ISO 5-2 (IT2.19)
Spot Size At Sample
1.8mm (.070 in) in scan direction x 2.5mm (.097 in) wide
Light Source
Gas Pressure @ 2850°K
Spectral Sensor
DRS Technology, 24 point engine, 31 point reporting
Spectral Range
400nm to 700nm
Illuminant Types
A, C, D50, D55, D65, D75, F2, F7, F11 & F12
Standard Observers
2° & 10°
Density Responses
Status T, E, I, & A (plus Status M on DTP41/T model)
Measurement Time
Approx. 0.25 sec/patch (7mm patch)
Reflection Measurement (DTP41 & DTP41/T)
Inter-Instrument Agreement
0.3 ÆE cmc avg. typical
(avg. based on 12 BCRA tiles)
Measurement Range
0.00D to 2.50D; 0 to 160% R (reflection)
Repeatability On White
0.2 ÆE max.; ±0.01D max
Linearity
± .01D or 1%
Transmission Measurement (DTP41/T)
Inter-Instrument Agreement
0.02D or 2% typical, 0 to 3.0D
Measurement Range
0.00D to 5.00D; 0 to 110% T (transmission)
Repeatability
± 0.01D or 1%, 0 to 3.5D (visual)
Media Thickness
0.08mm (0.003 in) to 0.6mm (.025 in) for optimum scanning
Maximum Length Of Sheet
1400mm (55 in) (scanning direction)
Measuring Location (From Edge)
Columns of patches must fall within 100mm (4 in)
insert-able area on standard model, and within 225mm (9 in)
insert-able area on DTP41W9 model. Built-in guide for 35mm film
Minimum Patch Dimensions
7.0mm (.28 in) high in scan direction
12mm (.47 in) width recommended
Patch Quantities
1 minimum, 100 maximum per pass
Recommended Leader Length
38mm (1.5 in)
Minimum Footer Length
Greater of 30mm or 2 patch + 2 gap heights
Data Interface
RS-232 serial interface with baud rates from 1200 to 57.6k
communication USB
Power Required
12v DC, Universal 100–240 VAC;
50–60 Hz adapter; 30W
Calibration
Calibration strips as needed
Environmental
+10° (50°F) to +40°C (104°F) operating
30% to 85% RH non condensing
Warm-up Time
None
Physical Dimensions
Height: 88mm (3.45 in)
Width: 184mm (7.25 in)
Depth: 114mm (4.5 in)
Weight
890g (1.96 lb), DTP41/T 1090g (2.40 lb)
Accessories Provided
Calibration Reference
Interface Cable: DB9 RS-232 and/or USB
AC Adapter
Link to x-rite for related information.
dtp41 pdf manual download
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