Note: The Filter Drive Card is available in two configuration. As part of the Tiger Controller or as a Standalone FW-1000. Except for the RAM Save / RAM Write command and status return results, operation is identical.
AC Input: 90-264 VAC, 3.3 A (peak), 50/60 Hz
AC In-rush Current (Cold Start): 7 A (maximum), at 240 VAC
2.0 A Fast Blow 250 VAC, 5x20mm H pack fuse - for 110-120 VAC Operation 1.6 A Fast Blow 250 VAC, 5x20mm H pack fuse - for 210-230 VAC Operation 3.3 A Fast Blow 250 VAC, 5x20mm H pack fuse - for 100-105 VAC Operation
The FW 1000 uses a unique drive mechanism to give the lowest vibration possible when rotating to different filter positions. The dynamic balancing requires a powerful servo motor with precise control in order to obtain simultaneously fast switching speeds and low vibration.
The filterwheel controller allows for flexible control of the wheel, either with serial RS-232 commands, or using TTL triggers and preprogrammed sequences.
The filterwheel can be mounted on just about any microscope. For the photo port, the filterwheel occupies the space allotted for the C-mount adapter on the microscope. An optional C-mount flange is mounted on the motor side of the wheel and the appropriate optional photo port adapter for the microscope is mounted on the other side. For an excitation filter, optional microscope specific lamp adapters are provided.
The FW 1000 control box provides a simple unit that houses multiple control panel cards and allows for future expansion. The Main Power Switch energizes the appropriate internal power supplies to energize the panels inserted into the unit. A FW 1000 system can be supplied with just a Filterwheel Control Panel, or with the optional Shutter Control Panel as seen in the photo above.
A FW 1000 Filterwheel Control Panel can handle two filterwheels and simultaneously move both wheels to the next set of filter positions. It may be controlled by the button or Trigger input on the panel. A Shutter Control Panel can handle two shutters, including the optional built in shutters available with FW-1000 filterwheels. Both filterwheels and shutters may be controlled by computer commands via the RS-232 connector on the Filterwheel Control Panel. The shutters may also be controlled via the switches or TTL Trigger inputs on the Shutter Control panel.
The FW 1000 Filterwheel Control Panel provides control for two filterwheels, W0 and W1. The filterwheels are connected to the controller via the W0 and W1 DB-9 Male Connectors on the front panel. Upon power up, any connected wheel will attempt to locate its HOME position and, if successful, its corresponding LED numeric display will indicate the wheel position. If no wheel is detected, the display digit will remain off. In the event of an unrecoverable error, the display will show the letter “E.”
Each press of the NEXT button advances the filterwheel(s) to the next pre-programmed filter position(s). In the event of an error, i.e., when an “E” is displayed on the LED display, holding the NEXT button down for 3 seconds will initiate a system reset. Holding the NEXT button down for more than 6 seconds will initiate a programmed sequence – equivalent to the serial ST command.
A TTL input may be connected to the TRIG IN BNC Connector for triggered sequencing of the filterwheel(s). The SYNC OUT BNC Connector provides a TTL pulse as soon as the wheel(s) reach the commanded position(s). The SYNC OUT also provides flexible synchronization pulses when using the filter wheel in the Spin/SYNC mode of operation.
The RS 232 DB-9 Female Connector may be connected to a host computer with a null modem cable for programming or controlling the FW 1000 card. This port can also be used to control shutters attached through the optional Shutter Control Panel. Baud rate limited to 9600.
The new standalone Filter wheel controllers(FW-1000-SA) has a USB to UART Bridge Virtual COM chip onboard, it lets user send serial commands over USB. Drivers for it are available at www.siLabs.com. Baud rate limited to 9600.
The FW 1000 Shutter Control Panel provides for control for two shutters, 0 and 1. The shutters are connected to the controller with the 0 and 1 6 Pin Mini Din Female Connectors on the front panel. Upon power up, any connected shutter will go to its default position of OPEN or CLOSED depending on the position of the shutter’s toggle switch and the type of shutter (normally open or normally closed). It should be noted that the panel/card will be set for either a normally open or a normally closed shutter at the factory. This setting can be changed using the Shutter Setup command (see page 35). The Shutter Control Panel is controlled internally through the Filterwheel Control Panel’s RS-232 computer control serial port.
The two toggle switches for shutter 0 and 1 at the top of the panel allow manual override control of the shutter. When the toggle switch is placed in the left position, the shutter control is in the RS 232 controlled state that defaults to the de-energized position of the shutter at power up. When the toggle switch is moved to the right position, the control panel will energize the shutter for that switch. It should be noted that the switch must be in the LEFT position to be able to control the shutter through the Filterwheel Control Panel’s RS 232 computer control port.
If the shutter has a built in internal position sensor, the corresponding LED will indicate the shutter is in its OPEN position if lit. If no internal position sensor is detected, the LED will always remain unlit.
A TTL input may be connected to the TRIG IN BNC Connector for external control of each shutter. A +5vdc signal applied to the internal pin of the TRG IN BNC connector (the outer connector is ground) will override any computer controls and energize the shutter.
Whether it be computer serial control, toggle switch control, or TRG TTL control of a shutter, an energize signal from any one of them will dominate, and that shutter will remain energized until all control sources return to their de-energized state.
As outlined below in figures 1 and 2, the filters should be loaded into the wheel prior to installation on the microscope. Change the filters through the port on the side opposite the motor. Depending on the microscope, it may be necessary to remove the coupling adapter to the microscope to have better access to the filter holders.
ASI FW 1000 filterwheels use a split retaining ring to hold filters, as shown above.
When correctly tightened, the threads and split-ring lock the filter securely in place. When removing, you can use a toothpick to “pop” the ring out of the threads and then spin the ring out.
Please note the correct orientation / direction of the filter when installing it in place; most filter manufacturers inscribe an arrow that points in the direction the photons are expected to travel.
The ASI system is designed to work smoothly with the wheel fully loaded with filters. However, absolute minimum switching impulse will occur when the wheel is loaded with four 3mm thick filters (total filter mass about 17gm). For best results, attempt to maintain a balanced wheel. The filters and slugs should be distributed evenly about the wheel axis to keep second order vibration minimized. For the fastest two color switching, place the two filters to be used in positions zero and one, and balance the wheel with filters or slugs in positions four and five. Bear in mind that any cumulative indexing errors that may occur are corrected whenever the wheel turns between the zero and one position. Hence, it is desirable to load commonly used filters in these positions so that the correction will naturally take place regularly.
Attach the filterwheel to the microscope using the mounting adapters supplied for your installation. The motor side on the filterwheel is located away from the microscope body for most installations. Attach the camera, detector, or lamp housing to the adapter on the motor side of the filterwheel.
In emission applications, the filterwheel is mounted between the photoport of the microscope and the camera. If you ordered your filterwheel for this application, an adapter specific to your microscope will be installed on one side of the filterwheel case. This adapter would mate with a photoport on your microscope. A male C-mount adapter shown in figure 3 will be installed on other side of the filterwheel case to mount a camera. The stainless steel portion of the C-mount adapter can be rotated to correctly position the camera. To rotate the C-mount adapter, use the 0.05” Allen wrench to loosen two of the three setscrews as shown in figure 3. After correctly positioning the camera, re-tighten these setscrews.
As shown in above figure, the filterwheel may be mounted between the lamp housing and the microscope lamp housing port to control the excitation wavelength.
WARNING: When using the filterwheel in this manner, a heat filter must be installed between the lamp housing and the filterwheel or damage to the wheel will occur. If your lamp housing does not have a heat filter built into it, a heat filter must be ordered from ASI. This filter will be installed between the lamp housing adapter and the wheel.
Plug the AC power cord into the rear of the controller. Attach the cable between the filterwheel and the controller. Connect the serial cable between the computer and controller.
Before installation on the microscope – check out the basic operation of the filterwheel and load your desired filters. The following Quick Start Procedure will walk you through these steps.
Plug the controller into an AC outlet and connect the filterwheel to the “W0” connector on the controller with the cable provided. Power up the filterwheel. Upon initialization, the wheel(s) will rotate to HOME.
For stand-alone filter wheel controllers the RS 232 serial link is used for communication. This is also true for RM2000 controllers with a filter wheel controller installed inside the same box. The serial link also provides direct control of the filterwheel(s) as well as diagnostic information. In Windows 7 or later it is suggested to use Putty or other serial communication program, or in Windows XP you can use the HyperTerminal program. Using HyperTerminal, set up the connection as “Direct to Com1.” Connect the provided “Null Modem” serial cable from COM1 on the computer to the RS 232 connector on the front panel of the FW 1000 controller
The FW 1000 controller uses the following RS 232 communication settings:
Default Serial Settings: 9600 Baud; 8 data bits; No Parity; 1 stop bit; No Flow Control
Set up Putty or HyperTerminal accordingly. In the ASCII setup section, be sure the checkbox “Send line ends with line feeds” is not checked.
In the TG-1000 “Tiger” modular controller, the filter wheel control card is treated mostly as any other card. Connect to the Tiger controller as you normally would (see Tiger RS-232 Communication tech note).
Note that the filter wheel has a different line termination than all other Tiger cards. Serial commands should be terminated by \r\n (<CR><EOL>) whereas the order is reversed for Tiger and MS2000 controllers. If you are using Micro-Manager there is a property in the comm card to set the correct setting for any manual commands sent.
When the controller is turned on, the following messages should be displayed in HyperTerminal:
RESET MOTOR 1 NOT RESPONDING 0>
Power up initialization
Printed when only one Filterwheel is attached
W0 digit of the numeric display on the controller should read
0 , corresponding to the HOME position of the filterwheel. The
W1 digit should remain off if only one wheel is attached.
Try a few of the following commands; what you send is shown in this TYPESET ; Controller printout is shown in this TYPESET
0> MP n n Move wheel “0” to filter position n, where n is any valid filter position.
0> HO Cause the wheel(s) to seek HOME
0> P1 1 Read the value of P1 (the second programmed filter position). Control indicates P1 for wheel “0” is set to 1
0> P1 3 3 Set the P1 value for wheel “0” to position 3. Control indicates P1 for wheel “0” is set to 3
0> ST Start a pre-programmed, timed move sequence.
0> HA Halt the move sequence
0> JK ERR Invalid command JK returns ERR string.
Next button on the controller. The wheel(s) will advance to the next position of pre-programmed sequence each time the button is pressed.
If you have more than one filterwheel attached to the controller, change the active wheel with:
0> FW 1 1 Now all input will refer to wheel “1” where appropriate
1> The prompt indicates your commands are directed to wheel “1”
See the command list at the end of this manual for a complete description of the FW 1000 command set.
The FW 1000 controller allows you to set up a series of filter positions that can be repeatedly sequenced in the order you desire. The sequence may be run with pre-set delays, with the front panel button, or with a TTL pulse connected to the front panel BNC connector. Alternatively, you may move both wheels to a pre-programmed position with the serial command, Gn , where n is the desired protocol position number.
Presently you may program up to 8 filterwheel positions for each wheel. You may also program a delay value for each step. The delay is used only when executing a time sequence using the ST (Start) serial command, and does not affect TTL-commanded sequencing. The wheel(s) will move to each programmed position in turn. The sequence will restart at the P0 position following the last position command (Pn) whose position for both wheels was not “-1”. Initially, all programmed wheel positions are set to -1 except for P0 and P1 which are set to HOME (0) and to Position 1, respectively, for each wheel. The delay values are initialized with a value of 500 milliseconds for all positions.
The table below illustrates an example program sequence of five positions:
|Command||Delay||Command||Wheel 0||Wheel 1|
In this example, the P2, P3, and P4 positions for wheel 0 are changed to positions 2, 2, and 3 respectively. The P2, P3, and P4 positions for wheel 1 are changed to positions 1, 4, and 0 respectively. For successive TTL pulses (or button pushes) the wheels will advance as follows:
|Pulse #||Wheel 0 Position||Wheel 1 Position|
If you were to issue the serial command G4 with the set-up above, the controller will move the wheels to the “P4” protocol position (i.e. Wheel 0, position 3 and Wheel 1, position 0). A subsequent TTL trigger would advance to P0 (i.e. Wheel 0, position 0 and Wheel 1, position 0).
If the serial command ST is issued, the wheels will advance from position to position with 500 ms delays between moves, moving continuously until the HA command.
Note: There is a HOME index on the encoder wheel located between the HOME (0) and the first (1) filter position. Each time the wheel passes this point, the position encoders are readjusted if necessary. This ensures that the wheel does not drift off its indexed position after many successive filter changes. The user should implement protocols that move the wheel across the index position (between positions 0 and 1) at least once in the course of the protocol cycle to ensure that the wheel does not drift from the indexed positions. The wheel will move the minimum distance between positions, so filter changes between the following positions will re-index the wheel: 0&1, 0&2, 0&3, 0&4, 7&1, 7&2, 6&1. Hence, it is recommended that you place your most commonly used filters in the HOME (0), 1, 2 and 7 positions.
The FW 1000 controller is shipped with default speed settings that yield modest switching speeds and fairly smooth operation. Typical adjacent-filter switching time is about 60 milliseconds as shipped. The user has full control of the motion control parameters to affect faster switching speeds if desired, or slower speeds for even less vibration if that is necessary.
Establish communication with a host computer so you can program the controller. Issue the command VB 2 This sets the verbose mode so that switching time, total move time, and maximum errors during move and settling are displayed following a move. Now if you issue a move command, following its completion, you will see the status line telling how long the move took.
0> HO HOME the wheel – should be at position 0
0> VB 2 Set controller to Verbose mode 2.
0> MP 1 Move to position 1
0>t:68 T:129 Em:10 Ef:-11
The line above shows that is took 68 milliseconds to get to position, and 129 milliseconds before all motors were completely turned off. Em and Ef show the maximum trajectory errors (in encoder counts) during the move into position, and during the settling period respectively.
You can change the run velocity VR , the up and down acceleration, AU and AD , or the servo motion parameters to affect the speed changes you desire (see page 32). You can see how your changes affect the switching speed and move errors when you make test moves. Once you are satisfied with your changes, you can save the settings to non-volatile (flash) memory with the serial command RS . Afterwards, each time you power up the controller, your settings will be used.
If you try to use settings that are beyond the capability of the motor and the controller to follow, you will get errors when a move is initiated. Under these circumstances, change the offending parameter to a more reasonable value, HOme the wheel to clear the error condition, and try again.
Rather than setting all of the motion control parameters yourself, you may also use one of the preset combinations using the SV command. The chart below shows typical switching times for the filter wheel for each of the nine presets available with the SV command. The graph shows both the time to obtain a clear aperture (CLEAR) and the time before the motors have completed motion (OFF). Times for switching to an adjacent position and the time for the longest possible move are shown. The effect of the number of filters loaded in the wheel shows up as a slightly longer settling time when the fastest switching speeds are used.
The user can expect significantly longer lifetime from the friction drive elements in the filter wheel if slower speeds are used. Running for extended periods of time with SV=8 or 9 may cause errors and overheating of the driver. The table below shows the values of the AU, AD, VR and KA parameters that are set for the various SV values. The filter wheel default parameters are equivalent to SV=5, shown in bold.
The controller normally leaves the factory with the correct offset programmed into the controller for the wheel purchased. If you are using a different wheel or the correct offset is no longer programmed into the controller, you can use the following steps to reset it correctly.
In some applications the user may wish to continuously spin the filter wheels to obtain relatively rapid switching of filter sets. For instance, with an 8 position filter wheel, filled with alternating 340nm and 380nm filters, switching speeds of about 10ms between filters is possible for calcium ratio experiments. The filter wheel has flexible sync pulse output that can be used to trigger data acquisitions synchronized with the filters reaching alignment. This provides a relatively inexpensive and simple way of achieving fast switching times for applications such as ratio imaging or photometry. The following serial commands are applicable to spin/sync operation:
VR Sets rotation speed in encoder counts/sec. (One turn is 1024 counts)
SF Starts or stops the wheel spinning.
NP Specifies the number of sync pulses per revolution of the wheel.
PH Specifies the relative phase of the sync pulses.
PL Specifies the duration of the sync pulses.
See the programming manual section for details of these commands. A simple way to verify operation of the spin/sync mode of operation is to use the SYNC output to power a LED light source. Properly adjusted, the LED should appear illuminated when viewed through the rotating wheel. The phase and pulse length of the sync pulse can be changed while the wheel is spinning so optimal timing can be verified. Observing the LED near the edges of the aperture can check for bleed-through from adjacent positions. Once the LED is observed cleanly in the aperture without any bleed through around the edges, the phase and pulse length parameters can be saved and the sync pulse will serve as the sampling gate for the detector.
The FW1000 controller can be remotely upgraded to the most recent firmware available. Please check the ASI website for details.
Servo or encoder error conditions are reported on the RS 232 port. Usually intermittent errors can be ignored. When unrecoverable motion errors occur, the motors will be turned off and the error condition will be indicated by an E on the LED display. This condition can be cleared by pressing the NEXT button to reset the controller, or by sending a HOME command to the offending motor.
The temperature of the driver transistors is monitored as well. If overheating occurs, the motors will be turned off and an H will be displayed on the LED display.
The FW 1000 controller responds to RS 232 serial commands. All characters are echoed by the controller except for the ? and control characters. The <DEL> and <BS> characters are not interpreted, so mistyping will result in erroneous commands. The FW 1000 controller uses the following RS 232 communication settings:
Default Serial Settings: 9600 Baud; 8 data bits; No Parity; 1 stop bit; No Flow Control
If a command is not understood by the controller, the string ERR is returned.
Commands that accept an input parameter return the current value of that parameter. If a new value is given in the command, the new value will be returned; if no value is given in the command, the current value will be returned. For example consider the velocity run command.
0> VR 3195 Sending only the command returns the current value.
0> VR 2000 1995 Sending the command with a new value, the program returns the working value (in this case there was a rounding difference from what was specified).
0> VR 1995
The command response is terminated with a <LF> <CR> followed by the prompt characters 0> or 1> depending on which wheel is actively taking commands.
The only exception to this standard is the busy query command described below.
Syntax : ?
The “?” command is immediately processed (no <CR> or <LF> required) and a single digit Busy Status is returned. The returned digit has the following meaning in MS2000:
|0||Neither wheel moving (not busy).|
|1||One wheel moving, but within tolerance for clear light path.|
|2||Two wheels moving, but both are within tolerance for a clear light path.|
|3||At least one wheel not in tolerance for a clear light path.|
|4||At least one wheel has not completed initialization. Supported in version 3.3 and later.|
|5||Error - requires a reset (F70) or power cycle to recover. Supported in version 3.3 and later.|
|6||Unknown status - inform ASI you received this status. Supported in version 3.3 and later.|
The return digit(s) have the following meaning from a filter wheel card in a Tiger controller:
|0||Neither wheel moving (not busy).|
|7||At least one wheel is off target.|
|8||A runaway on at least one wheel was detected.|
|9||At least one wheel did not settle on target on time.|
|10||An overflow was detected.|
|11||A homing error was detected.|
|12||At least one wheel is busy.|
|13||An unknown command was issued.|
|14||At least one wheel is disabled.|
|15||A large overflow was detected.|
|16||The current wheel is off target.|
The following commands apply to both or neither wheel, and do not depend on the currently selected wheel:
Syntax : F70
Resets the filterwheel processor. Resulting behavior is equivalent to cycling power. Supported in version 2.1b and later.
Syntax : FW n
Sets the current Filterwheel for subsequent commands. Prompt shows currently selected wheel, e.g., 0> is result of FW 0 command. If the selected wheel is HOMED and ready to go, the FW command returns the selected wheel as normal. If the wheel is not ready for any reason, the response ERR is returned. Example:
0> FW 1 1 Normal – switch to FW 1
1> FW 0 ERR FW 0 not ready
0> Although FW 0 not ready – can still change FW 0 parameters.
Syntax : HA
Stops all motor movement; Halts protocol execution.
Syntax: NF n
Sets the number of slots in the wheel, e.g., 6 or 8. (Normally set at the factory.)
Syntax: NP n
Sets the number of synchronization pulses/revolution of the filter wheel. The pulses will be uniformly spaced and are synchronized with wheel’s position encoder. Default setting is 1.
Restore factory default parameters.
Syntax for FW-1000: RS
Syntax for TG-1000: RW
Save current parameters to non-volatile (flash) memory.
Recall last saved parameters.
Dumps the working variables stored in RAM to the RS 232 port.
Dumps the variables stored in the non-volatile (flash) memory to the RS 232 port.
Syntax: PL n
Sets the pulse length of the Sync Out signal to n milliseconds.
Syntax: PH n
Sets the relative phase of the Sync Out pulses when in the Spin/Sync mode of operation. The phase is expressed in encoder counts. There are 1024 counts in a full revolution.
Starts timed protocol. The protocol will start at the current protocol position. After a reset, this is the position P0. Use the Gn command to set the initial position before starting the protocol. Use Halt command HA to stop the routine.
Causes the wheel(s) to move to settings for Protocol Setting n, where n is a number in the range [0 7].
Syntax: VB n
Selects information stream from processor to RS 232
|n=0||Normal mode – prompt and error messages only.|
|n=1||Encoder position information.|
|n=2||Show move times and motion-error maximums.|
|n=3||Debug mode shows process steps.|
|n=4||Other verbose debug info.|
|n=5||No serial output in response to some commands. Supported in version 2.0f and later.|
|n=6||No prompt characters (e.g., 0>) output in response to any commands. Supported in version 2.0g and later.|
|n=7||Same as mode 6 with addition of no “MOTOR x NOT RESPONDING” reports on boot. Supported in version 3.3 and later.|
Returns the Version Number of the firmware.
The following diagnostic commands are included for completeness, but may not be included in future releases of the firmware.
Sends trajectory information to the serial port about the last completed move.
Syntax: DE n
Sends the logged error buffer to the serial port. Errors are reported whenever the motors are turned on to full power. This is expected and common when running with modest to fast switching speeds. DE -1 Clears the error buffer.
The following commands set parameters that apply only to the currently selected wheel:
Causes current wheel to seek its home position.
Syntax: MP n
Move to filter position n , where n is a valid filter position.
Syntax: OF n
Sets the home index offset for the wheel to n . The value n should be in the range [0 128] such that a HO command returns the wheel centered on the optical axis. Once determined, this value should be saved to flash.
Syntax: P[m] n
Sets protocol entry m to filter position
m is a number in the range [0 7] and
n is a valid filter position.
Syntax: D[m] n
Sets the delay time prior to execution of move to protocol entry m to the value n where m is a number in the range [0 7] and n is the delay time in milliseconds.
Syntax: AU n
Sets the acceleration value in encoder counts/sec/msec. Default is 150. Increase up to 400 for faster acceleration but more vibration.
Syntax: AD n
Sets the de-acceleration value in encoder counts/sec/msec. Avoid values greater than 200 or excessive driver current can result in overheating.
Syntax: LM n
Determines the servo behavior upon completion of a move.
|n=0||Default – servo remains active for 200ms after completion of a move and then is turned off.|
|n=1||Servo is always active. You cannot position the wheel by hand in this state.|
Syntax: SF n
Initiates the Spin/SYNC mode.
|n=0||Stops the spinning Wheel.|
|n=1||Starts the current wheel spinning.|
|n=2||Starts both wheels spinning together available in Tiger firmware version 3.2+ only , not in standalone FW-1000|
|n=3||Similar to n=1, except Spins wheel in reverse direction available in Tiger firmware version 3.2+ only , not in standalone FW-1000|
Syntax: SV n
Selects a consistent set of preset acceleration and speed parameters. Supported in version 2.4 and later.
|n=0||Default - directly set and saved AU, AD, and VR parameters are used.|
|n=1||Slowest and smoothest switching speed.|
|n=2 to 8||Intermediate switching speeds.|
|n=9||Fastest and but least reliable switching speed.|
Syntax: VR n
Sets the maximum run velocity in encoder counts/sec. Default is 2000. Increase up to 4000 for faster top speed but more vibration. For spinning the filter wheel, can be increased up to a maximum of 12500. Expect some servo errors at high speeds.
Syntax: GO n
Moves to absolute encoder position
n. The range of n is +/-32768. The motor will move the commanded distance, but the final position will reflect the current location between 0 and 1023 of the wheel’s rotation.
The following commands are used to control shutters with an SH 2 controller in the same cabinet as the FW 1000 controller. The parameter n may have any value from zero to (2N 1), where N is the number of shutter controller cards in use.
Syntax: SO n
Opens shutter number n.
Syntax: SC n
Closes shutter number n.
Syntax: SQ [n]
Returns a decimal status byte from a shutter control register. The n parameter is optional in the Shutter Query command. If no n is specified, then the command returns the status byte from the most recently used shutter controller. If no shutter commands have been issued since the last system startup, then the command returns the status byte from the controller of shutters 0 and 1. If no SH 2 Card is present, 0 is returned.
In the descriptions of Bit 0 and Bit 1 below, an energized, normally open shutter is closed; a de-energized, normally open shutter is open; an energized, normally closed shutter is open; and a de-energized normally closed shutter is closed. In other words, a de-energized shutter is always in its normal state. The binary equivalent can be decoded as follows:
|Bit 0||1 = Shutter 0 is de-energized|
|0 = Shutter 0 is energized|
|Bit 1||1 = Shutter 1 is de-energized|
|0 = Shutter 1 is energized|
|Bit 2||1 = Shutter 0 is closed or has no sensor|
|0 = Shutter 0 is open and has a sensor|
|Bit 3||1 = Shutter 1 is closed or has no sensor|
|0 = Shutter 1 is open and has a sensor|
|Bit 4||SH2 Card is present|
Syntax: SS x
Supports shutter control. Normally, the SC command causes the controller to energize a shutter, and SO causes the controller to de energize it. Most shutters are normally open; i.e., open, unless energized by the controller via the SC command. The SS parameter x is a binary number representing eight bit positions, i.e., an integer in the range 0…255. Within x, if some bitk is set, then shutter k is normally closed. With this setting in effect, the effects of SO and SC are reversed. Instead of SC causing the controller to energize the shutter, SO energizes it, and vice-versa. Once determined, this value may be saved to non-volatile (flash) memory using the RS command.
The default value of x is zero, denoting that all shutters are normally open.
Examples: SS 2 is correct if Shutter 1 is normally closed, because x has Bit 1 set. SS 3 is correct if shutters 0 and 1 are normally closed, because x has Bits 0 and 1 set.
The following parameters affect the motor positioning algorithm. Change these at your own risk.
Syntax: KA n
Syntax: KV n
Syntax: KP n
Syntax: KI n
Syntax: KD n
Syntax: KR n
|W0 & W1 Filterwheel Connectors|
|1||Motor +||0-24 VDC, 6 Amps Max|
|2||Motor -||0-24 VDC, 6 Amps Max|
|4||ENC A||Input: Std TTL|
|5||ENC B||Input: Std TTL|
|6||Motor +||0-24 VDC, 6 Amps Max|
|7||Motor-||0-24 VDC, 6 Amps Max|
|8||Index||Input: Std TTL|
|9||+5 Vdc||6 Amps Max|
|RS 232 Serial Connector|
|2||TX||Follows RS-232 standard|
|3||RX||Follows RS-232 standard|
|1||TTL Next Pulse||Input: Std TTL|
|1||SYNC OUT||Output: Std TTL|
|Shutter Control 0 & 1 Connectors|
|1||Shutter +||~5msec 60vdc peek at start, 5vdc Holding Voltage when energized|
|2||Shutter -||Controlled Ground|
|3||Position Sensor LED +||+5 vdc|
|4||Position Sensor GND||Ground|
|5||Position Sensor Return||+5vdc TTL Signal|
|6||Position Sensor +5vdc||+5 vdc|
|TRG 0 & 1 BNC Connectors|
|Methods of Control||Serial Interface|
|and Front Panel|
|Number of Shutter Channels per Card||Two|
|0%-to-100% Opening Time from Trigger (N.C. shutter)||8 ms|
|100%-to-0% Closing Time from Trigger (N.O. shutter)||7 ms|
|Minimum 50%-to-50% Open Time (N.C. shutter)||5 ms|
|Minimum 50%-to-50% Closed Time (N.O. shutter)||13 ms|
|Minimum Total Window 0%-to-0%||14 ms|
|Minimum Trigger Width||7 ms|
|Peak Unsustained Repetition Rate||40 Hz|
|Maximum Sustained Repetition Rate||5 Hz|
On filterwheel jumper JP4, connect 1-2 and 3-4.
On the shutter card jumper J1, connect 1-2, 3-4, and 5-6.
A list of recent errors are available through the Dump Errors (DE) command.
|OVERSHOT||10||Plus axis number.|
|RUN_AWAY||30||Plus axis number, followed by mode. See mode table below.|
|LARGE_OVERFLOW||50||Plus axis number.|
|SLIP_ERROR||70||Plus axis number.|
|PAST_ERROR||80||Plus axis number.|
|ERROR_OVERFLOW||90||Plus axis number.|
|KP_ERR_OVERFLOW||100||Plus axis number.|
|KV_SPD_OVERFLOW||110||Plus axis number.|
|KI_SUM_OVERFLOW||120||Plus axis number.|
|ERR_INTEGRAL_OF||125||Plus axis number.|
|KD_TRM_OVERFLOW||130||Plus axis number.|
|KA_TRM_OVERFLOW||140||Plus axis number.|
|ENCODER0_ERROR||160||Plus error number.|
|ENCODER1_ERROR||170||Plus error number.|
|MOVE_OVERTIME||180||Plus axis number.|
Applied Scientific Instrumentation, Inc., hereafter referred to as ASI, guarantees its equipment against all defects in materials and workmanship to the original purchaser for a period of one (1) year from the date of shipment. ASI's responsibility to this warranty shall not arise until the buyer returns the defective product, freight prepaid, to ASI's facility. After the product is returned, ASI at its option, will replace or repair free of charge any defective component or device that it has manufactured. The warranty set forth above does not extend to damaged equipment resulting from alteration, misuse, negligence, abuse or as outlined below:
1. Equipment not manufactured by ASI that is offered as part of complete systems carry the original equipment manufacturer's warranty.
THE WARRANTY AND REMEDIES SET FORTH ABOVE ARE IN LIEU OF ALL OTHER WARRANTIES. APPLIED SCIENTIFIC INSTRUMENTATION, INC. EXPRESSLY DISCLAIMS ALL OTHER WARRANTIES WHETHER EXPRESSED, IMPLIED OR STATUTORY, INCLUDING THE WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE AND AGAINST INFRINGEMENT.
In no event will ASI be liable for incidental or consequential damages, even if ASI has been advised of the possibility of such damages howsoever, arising out of the sale or use of the products described herein.