EP3602164A1 - Programmable microscope control unit having freely usable connections, microscope system having a microscope control unit, and method for operating a microscope control unit - Google Patents

Abstract

The invention relates to a microscope control unit (100) having at least one connection (101), which can be connected to one or more electrically controllable microscope components (201, 202, 203, 204, 301, 302, 303, 304) or other electrically controllable components, wherein at least one connection parameter of the at least one connection (101) can be configured by means of programming, wherein at least one script having script commands is provided on the microscope control unit (100), and wherein the at least one connection (101) is controllable by means of the script commands. The invention further relates to a microscope system having such a microscope control unit (100) and having at least one microscope or other electrically controllable component.

Description

 Programmable microscope control unit with freely usable connections, microscope system with a microscope control unit and method for operating a microscope control unit

description

The present invention relates to a microscope control unit having at least one connection which can be connected to one or more electrically controllable microscope components or other electrically controllable components, and to an automated microscope system having such a microscope control unit and to a method for operating such a microscope control unit.

State of the art

As an automated microscope usually microscopes with one or more electrically controllable components are referred to, for example, where a digital camera acts as a detector and the images are displayed on a monitor or, for example, the light source is controlled. It can also be a digital microscope, which is characterized by the fact that it dispenses with a tube for a visual insight on the microscope image and generates only a digital microscope image and displays this on a display or monitor. Such automated microscopes usually have a microscope control unit, which comprises an electronic unit and a control program, the so-called firmware. In the firmware, for every microscope component, which should be electrically controllable, a program part be present. This applies, for example, to components such as camera, x / y stage, zoom, lighting, etc. If further controllable components are to be connected to the microscope, the firmware must be changed and subsequently changed on existing microscopes. The microscope control unit can be connected to input devices, such as rotary knobs, switches or touchscreens, but also to a user interface on conventional PCs, which runs by means of a so-called human machine interface (HMI software for human machine interface) ,

For example, DE 10 2010 063 392 A1 shows a digital microscope, which dispenses with visual inspection, and with an image acquisition device set up for the optical and digital acquisition of an object to generate an object image, and with a display of the object image in a display region and for recording equipped with inputs in the display area formed sensor screen, wherein the microscope for changing settings of motorized and / or electrically controllable microscope components on the microscope is set up based on the detected in the display area of the touch screen inputs.

In particular, modern microscope systems have a microscope control unit, associated electrically controllable microscope components and a computer (PC) for operation. Within limits, the PC can also be used to offer the user, in a software program, automated sequences and boundary conditions for selection, which are then executed by the microscope control unit. As a result, processes that are not offered can not be executed.

EP 1 426 754 A1 relates to the control of an image recording, in which a control unit controls the devices required for image recording and a computer unit processes the data of the recorded images. To get the speed To increase the flexibility and reproducibility of image acquisition, it is proposed to combine control commands for image acquisition into at least one script and to transmit at least one script from the computer unit to the control unit.

It is desirable to break these limits in the predetermined automated processes and to make any electrically controllable components available by means of the microscope control unit. Disclosure of the invention

According to the invention, a microscope control unit with at least one connection which can be connected to one or more electrically controllable microscope components or other electrically controllable components, a microscope system with such a microscope control unit and a method for operating such a microscope control unit with the features of the independent patent claims are proposed. Advantageous embodiments are the subject of the dependent claims and the following description. In the context of the invention, a microscope control unit with at least one connection, which is connectable to one or more electrically controllable microscope components or other electrically controllable components, presented, wherein at least one connection parameter of the at least one terminal programmatically configurable, wherein on the microscope control unit at least one Script is stored with script commands, and wherein the at least one port is controlled by means of these script commands. A microscope control unit according to the invention has the advantage that the at least one connection can be freely used by the user. The term "connection" refers to an electrical interface serving as inputs or outputs for electrical control signals to electrically controllable components and / or electrically controllable components, which are arranged inside or outside the microscope system, are definable.

"Free" means, in particular, that the connection in question does not serve a predetermined purpose, but is freely usable and, in particular, freely definable in its function or protocol, so that the connection can be used in a predefined way by means of appropriate script commands In particular, any electrically controllable microscope components or other components operated in conjunction with the microscope can be controlled by the microscope control unit when executing the script.

For example, the microscope control unit can be set up to control any combination of one or more of the following electrically controllable microscope components by means of the script commands via the at least one connection:

 a motorized XY table,

 a motorized Z-drive for adjusting the distance between a lens and a sample,

 a motorized turntable with optical components, for example an incident light turntable (IL Turret) with a plurality of optionally insertable into the beam path of the microscope Fluorenzfilter cubes, an electrically switchable light source,

 a laser,

 an acousto-optic beam splitter (AOBS),

 an acousto-optic modulator (AOM),

 a digital camera,

a detector, such as a hybrid detector or a photomultiplier. Alternatively or additionally, the microscope control unit can be configured to control other electrically controllable components by means of the script commands. In this case, electrically controllable components are conceivable which can be operated in conjunction with the microscope and a test carried out therewith. For example, the experimental setup around the microscope may require a controllable climate chamber or a water supply or discharge or a gas supply or discharge (eg evacuation to a certain negative pressure). In this case, for example, an electrically controllable water pump or gas pump or vacuum pump or an electrically controllable climate control unit could be controlled by the microscope control unit via the at least one connection.

The invention offers the advantage that the user of the microscope himself can select which electrically controllable components he wants to use and couple to the microscope. This free configuration of the microscope with microscopically adapted to the microscope microscope components and the control of these microscope components is independent of whether they were already known at the time of manufacture of the microscope or routinely supported by the firmware of the manufacturer of the microscope control unit or not. A disadvantage of the earlier solution lies in the fact that each component to be controlled had to be permanently implemented in the microscope control unit. Thus every smallest extension of the experimental set-up caused a change in the microscope control unit due to a newly used, electrically controlled component. For example, a new camera type with new trigger behavior inevitably required a factory change to the microscope control unit.

In contrast to conventional microscope systems, in the context of scripts running on the microscope control unit, it is no longer possible to use only predetermined microscope components, but any newly added microscope components or other components in the program sequence. if they can be controlled by means of the at least one terminal of the microscope control unit.

Preferably, the at least one connection parameter of the at least one connection can be configured programmatically by means of the script commands. In this way, both the configuration of the terminal and its subsequent activation can be realized by means of one and the same script. This is very user friendly. Alternatively or additionally, a configuration environment may be provided in the form of a user program, for example in the form of the programming device or PC mentioned below.

The at least one programmably configurable connection parameter preferably comprises at least one parameter which configures the connection as:

 - input or output

 - analog or digital

 - Current or voltage interface.

The at least one programmably configurable connection parameter preferably comprises at least one parameter selected from:

 - Communication protocol

 - Transfer rate

- signal amplitude.

The configuration may include any combination of parameters.

Thus, it can be provided, in particular, that the at least one connection comprises an input and is optionally configurable as an analog input or as a digital input. Alternatively or additionally, special connections designed as analog inputs and special connections designed as digital inputs may also be included and configurable. Such an embodiment is easier to manufacture.

The same applies preferably also for the outputs. Preferably, the at least one port comprises an output and is optionally configurable as an analog output or as a digital output. Alternatively or additionally, special connections designed as analog outputs and special digital outputs are also included and configurable.

According to another embodiment, the at least one port comprises a so-called general purpose input / output (GPIO) port. It is then a connection whose behavior, independently of whether as input or output, is freely programmable. Such an embodiment offers great flexibility.

In an advantageous embodiment, the microscope control unit is configured to be able to process script instructions of a predetermined script instruction set. This facilitates later programming by a user. Preferably, the script command set also includes script commands which are assigned no functions of the at least one port, but other functions, in particular program flow operations (such as waiting, repeating, loops, etc.), arithmetic operations (such as adding, multiplying, etc.), etc.

In a further advantageous embodiment of the microscope control unit, the script commands of the at least one script can be selected from the script command record by a user, and their sequence in the script can be specified by the user. In other words, the user can make the script substantially free using the instruction set. In a further embodiment, the microscope control unit is set up to be data-transmitting connected to a user interface via which the user can select the script commands of the at least one script from the script command set and via which the sequence in the script can be predetermined by the user.

For this purpose, the microscope control unit can be designed such that the user interface is designed as a hardware-based input unit of a programming device.

In another embodiment of the microscope control unit can be provided that the user interface is designed as a user interface of a running on a separate processing unit, in particular PC, user program. In particular, the user program can be a (pure) programming environment or an operating program for the microscope system.

For this purpose, the microscope control unit is preferably configured to be connected to a PC for data transmission. On the PC, in particular, HMI software can be executed which serves as a user interface by being implemented as a user interface of the user program. From there, the transmission of the script to the microscope control unit, by means of which the microscope system is operated. This makes the programming and / or operation of the microscope system very convenient and easy. At the same time, the PC can also be used for visualization, for example of recorded images or of any measured values.

After compiling the script, it may also be stored in a volatile memory, for example in a cache memory, or in a non-volatile memory of the operating PC or the microscope control unit or an external memory or a server. Another variant of the microscope control unit can be designed so that the script can be transferred as a text file to the microscope control unit. It is advantageous if the script is received in a text format, for example ASCII, ANSI or Unicode / UTF, since this ensures great compatibility.

Preferably, the microscope control unit is designed for fast and user-friendly control of the at least one connection by assigning it a control program with an interpreter for the script, which converts the script commands into functions of the at least one connection. This provides the ability to conveniently transfer the script to the microscope control unit in an intelligible or readable form, i. as a sequence of textual script commands. A compilation step before transfer can be omitted, so that in particular the programming device does not have to be adapted for compilation for different target systems. This advantage is achieved because the interpreter contained in the control program is not part of the user program. In an embodiment of the microscope control unit, the control program is stored in the microscope control unit itself. Alternatively, the control program is stored in an assembly outside the microscope control unit.

In a further refinement of the microscope control unit, the latter has an electronics unit and comprises the associated control program with an interpreter for the script.

The microscope control unit according to the invention not only allows substantially simpler adaptations of the functional assignment of the at least one connection to newly adapted electrically controllable microscope components or other electrically controllable components of the experimental setup. By the omission Compiling and using the script with the aid of the interpreter, in addition, significantly higher speeds can be achieved in the control of the at least one connection and the associated electrically controllable microscope components or components. For this purpose, in a further embodiment of the microscope control unit, the script commands are implemented as real-time commands for controlling the at least one connection.

By selecting the script commands, a plurality of functional assignments of the at least one connection of the microscope control unit can be realized. For example, a channel type for the at least one port can be defined for the microscope control unit by means of the script commands.

Likewise, it is possible for at least one variable and / or at least one command and / or at least one script and / or at least one function block to be provided by means of channels in the microscope control unit by means of the script commands.

Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

The invention is illustrated schematically with reference to an embodiment in the drawing and will be described below with reference to the drawing.

figure description FIG. 1 shows schematically in a block diagram a microscope system according to a preferred embodiment of the invention.

Figure 2 shows schematically the microscope system of Figure 1 in another schematic view.

FIG. 3 shows schematically in a block diagram a sequence of an exemplary experiment using a microscope system according to the invention.

FIG. 4 schematically shows, in a block diagram, the course of the experiment when using a microscope system according to a preferred embodiment of the invention. FIGS. 1 and 2 schematically show a microscope system according to a preferred embodiment of the invention. The microscope system has a microscope control unit 100 according to a preferred embodiment of the invention in a running on the microscope control unit 100 script for the use of freely usable connections in the form of inputs and outputs 101, with which one configured here as a control PC 10

 Human / machine interface (HMI) and a plurality of microscope components 200, 300 are signal transmitting connected.

The microscope components can be subdivided, for example, into internal microscope components 300 and external microscope components 200. However, this subdivision is immaterial to the invention. The internal microscope components 300 are characterized in that they are mounted on or in the microscope chassis 1 and are considered as part of the microscope, such as an IL-turret 301, a Z-drive 302, a Objektivrevverver 303, etc., whereas as external microscope components 200, for example, an XY table 201, a lighting device (possibly with shutter) 202, a Camera 203, etc. are viewed. Although these may also be mounted on the microscope chassis 1, they are usually not regarded as part of "the microscope". As far as the microscope components 200, 300 each have a controllable actuator (for example electric motor), they can be controlled in the context of the invention in a script running on the microscope control unit 100. The script comprises a sequence of selected script commands to which functions of the inputs and outputs of the microscope control unit 100 are assigned. Such functions include, in particular, reading and writing functions.

The control of these microscope components 200, 300 thus takes place via the microscope control unit 100, which is also referred to as "microscope master." The microscope master can be implemented by a microcontroller, DSP (Digital Signal Processor) or FPGA (Field Programmable Gate Array) ,

Some components have dependencies on other components. For example, it may be necessary for the Z-drive to be lowered prior to moving the nosepiece to prevent a collision of lenses with the XY-table. The dependencies, which are absolutely necessary to ensure operational safety, are referred to as critical dependencies and are preferably implemented firmly in the microscope master. That When a movement of the nosepiece is controlled, the microscope master automatically controls the Z-drive accordingly. This can include lowering the XY table, then rotating the nosepiece and, if necessary, lifting the XY table.

With a solution according to a preferred embodiment of the invention, it is possible to freely configure the control and dependencies of all components (external and internal). The configuration preferably takes place via HMI, for example PC 10, where the connections to be used are declared to the components to be controlled and the dependencies of the connections to one another be configured. The configuration can be done completely or in parts at runtime.

To use the individual inputs and outputs (ports), according to the preferred embodiment described herein, each port receives a unique number, the channel number. These channel numbers are assigned to the inputs and / or outputs of the microscope control unit 100 by appropriate script commands. In particular, each electrically controllable microscope component can be assigned at least one channel, wherein each channel in the script is configured by appropriate script commands as input and / or output for sequential or parallel processing.

The channel number is used to access the script, which is designed as part of the control program of the microscope control unit, that is to say of the microscope master 100. The script defines the program flow using channel numbers. The available script instructions are fixedly implemented in the microscope master 100, here preferably in an interpreter running on the control program of the microscope master 100, and provide rudimentary instructions, for example 'writing', 'reading', 'adding' or 'multiplying' ren ', which are used in particular for processing the defined channels. The available set of instructions is called a instruction set. For example, the microscope master can be set up to be able to process one or more of the following commands, to which functions of the inputs and outputs of the microscope control unit 100 are partially assigned.

- NOP: Do not perform any operation. This statement generates a minimum delay

- SET CHANNEL: Sets the value of a channel. - WAIT CHANNEL: Waits until the specified value is reached.

- SET CHANNEL CONDITITIONAL: Sets the value of a channel if a condition is met.

- COPY CHANNEL VALUE: Copies the value of one channel to the value of another channel

SET SCRIPT INSTRUCTION: Sets the instruction counter of the main processor of the microscope control unit 100 to the predetermined one

Value.

- LOOP SCRIPT: repeats the current script as many times as given. - WAIT TIME: Waits for a given time.

- TIMESTAMP: Creates a timestamp.

- ADD CHANNEL: Adds two channel values and assigns the result to a channel.

- SUB CHANNEL: Subtracts two channel values and assigns the result to a channel.

The microscope control unit 100, that is, the microscope master, executes scripts in a timer with temporal grid, wherein the time interval for the temporal grid is freely selectable. This offers a real-time capability for the running control program of the microscope control unit 100. Real-time systems are characterized by the fact that a result of an arithmetic operation (eg process or task) is guaranteed within a defined time interval, ie before a certain time limit. In a real-time system, for example, a so-called "real-time" system runs on the processor of the microscope control unit 100 for this purpose. Operating system that regulates the different processes and tasks. Alternative solutions are also known which do not require a real-time operating system. This is made possible, for example, by the use of state machines (statemachines) and interrupts.

The number of scripts and the number of script commands defined therein are not limited or only by the memory location of the microscope control unit 100, that is, the microscope master, according to the preferred embodiment described here. Furthermore, scripts can be started and stopped, for example by user input from the PC 10. Also, according to the preferred embodiment described here, it is possible to start a script from another script. The script itself also has an interface and a freely definable channel number, as a result of which a script can be viewed like any other channel with all available operations.

Preferably, the microscope control unit 100 is configured to provide different types of channels, such as e.g. one or more of type 'variable', 'hardware', 'command', 'script' and 'function block'. Each instance of a channel type is assigned a unique channel number. Following are some examples and definitions explained:

- Variable: A variable can be written and read. Hardware: A hardware channel is any analog or digital input or output. This channel type is used, for example, to trigger external components. For synchronization with an external component, such as a camera, for example, a digital input hardware channel and a digital output hardware channel are defined. Using both channels, trigger conditions can be implemented. Another example is generating any output voltage to control an external component, such as a light source. The value of the output voltage is set out of a script. Command: A command describes an ASCII string for communication with a component. The ASCII string to be used is defined prior to use and can have both a static and a dynamic part, with the dynamic part always being assigned to the variable type. The dynamic component can be used, for example, to set the position of a component.

For example, the string "76022 position" is used to set the position of the nosepiece, where the position can be either dynamic or static.

Example of a static position:

 "76022 1" => Setting the nosepiece to position 1

 "76022 2" => Setting the nosepiece to position 2 Example of a dynamic position:

 "76022 position" => "position" as a variable. When using the command in the script, the value of the variable is read out and adopted as a position specification.

- Script: A script consists of any number of sequential commands for processing channels.

Function block: A function block describes the linking of channels, whereby the function can be a logical, for example "AND" or "OR" or arithmetic "ADD" or "MULTIPLIER" as well as a permanently defined or freely definable LUT (look-up table). In order to carry out an exemplary experiment by means of a control program running on the microscope control unit 100, the microscope master, first the components and parameters to be used are selected (during the programming) and the time sequence is configured. The selection and configuration of the script commands in the desired order, so the definition of the script, for example, via the PC 10 in a dedicated input menu. This input menu represents the user interface, which is designed as a user interface of an application program, with which desired script commands can be selected from the script command set and whose sequence can be specified in the script.

In the following example, the sequence of an experiment is shown from the components XY table 301, illumination 302 and camera 303. This process is repeated n times within an experiment. The process includes (after configuration / declaration), for example, the following steps:

1. Positioning XY table

 a) Start positioning

 b) Wait until positioning ends

 2. Set illumination intensity

 3. Camera direction

 a) Open the shutter

 b) trigger signal to camera (preferably coincident with a) to avoid jitter)

 c) Wait for the exposure time

 d) Close shutter

 e) trigger signal to camera (preferably coinciding with d) to avoid jitter)

 4. Wait until the camera has transferred the image data to the PC

a) Waiting for trigger signal from camera to microscope master In a method according to a preferred embodiment of the invention, this means that the control program first declares the components to be used XY table 301, camera 303, lighting 302 with shutter in accordance with the script by the interpreter in the control program, the script in corresponding (machines -) commands to the inputs and outputs, ie in commands to the interfaces, converts. The interfaces or channel numbers of the components may look like this, for example:

 1. XY table: command to position

 2. Illumination: command to set the intensity

 3. Shutter: Hardware I / O on microscope master, as digital output

 4. Camera Imaging: Hardware I / O at the Microscope Master, as digital output

 5. Camera image transmission: Hardware I / O on the microscope master, as a digital input

 6. Exposure time: variable

Subsequently, the user creates on the PC via the user interface, for example, a script with instructions to edit the time sequence. The script can look like this:

 1. SET CHI, value 0 => Cancels the command for XY table positioning

2. WAIT CHI, value 1 => Waits for the command to be executed

3. SET CH2, value 0 => Cancels the command for setting the illumination intensity

 4. WAIT CH2, value 1 => Waits for the command to be executed

5. SET CH3, value 1 => open shutter

 6. SET CH4, value 1 => start camera exposure

 7. WAIT Time, value off CH6 => camera exposure, wait until time has expired

 8. SET CH3, value 0 => close shutter

 9. SET CH4, value 0 => Stop camera exposure

10. WAIT CH5, value 1 => Wait for camera image transfer completed 11. Loop, 100 => repeats the previous instructions 100 times

For the above-described experiment, a solution not according to the invention (FIG. 3) will now be compared with a solution according to a preferred embodiment of the invention (FIG. 4).

Not inventive solution

 A disadvantage of such a solution is that in a control program running on the microscope master no access to certain microscope components, such as e.g. XY table control, Z-drive, IL-turret is possible. These must be controlled by a user program running on the PC so that no real-time experiment is possible. The type and number of electrically controllable components is limited by the firmware specified by the manufacturer of the microscope system or the microscope control unit.

Start Loop

 1. PC sets command to move from XY table to microscope.

 2. PC is waiting for execution

 3. PC sets command to Z-shoot procedure on microscope.

 4. PC is waiting for execution

 5. PC sets command to move IL-Turret to microscope.

 6. PC is waiting for execution

 7. PC issues command to start a real-time experiment.

 => Start of real-time experiment in a microscope.

 a) microscope master performs

 i) Shutter

 ii) Camera

 b) microscope master execution end

 8. PC is waiting for execution

End loop For steps 1-8, a time T is needed.

Solution according to a preferred embodiment of the invention

Since the microscope control unit 100, the microscope master, is set up to execute a script with script commands and assign the script commands selectable functions of the inputs and outputs by means of the interpreter in the control program of the microscope control unit 100, all steps of the experiment in the context of a on the Microscope control unit 100 running control program to be performed.

The user sets the script with the script commands for assigning the channels before the experiment. It also configures the ports to use, such as the protocol to use, and so on. The script prepared by the user contains the script commands selected in the order selected. By means of the interpreter of the control program, the script is converted into commands for configuring the connections, for determining the channels of the inputs and outputs of the microscope control unit 100, and thus for commands for controlling all electrically controllable components. This starts the execution as a real-time experiment.

1. PC transmits the script prepared by the user to the microscope control unit 100, the microscope master

 2. Microscope Master starts interpreter and script execution

 3. Microscope Master starts interpreter for script execution

 Start Loop

 a) Script commands directly control components

 i) Move the XY table

 ii) Z drive

 iii) operating the incident light turntable (IL-turret)

iv) set lighting v) Camera direction and shutter control

 b) Script reports to microscope master: Execution end

 End loop

 4. Feedback to PC is omitted

For the steps 1-3, a time T * is needed, which is significantly shorter than the time T for the non-inventive experiment due to the previously described reduced responsibility changes. It is therefore not necessary for the PC to first calculate the assignment of the channels for each individual experiment step during the experiment and to generate the individual, current commands one after the other. Thus, each subsequent control command is only transmitted to the microscope control unit 100 by the PC after feedback about the completion of the respective preceding experiment step. This leads, technically, to a constant change of responsibility between the PC and the microscope control unit 100, whereby time is consumed. In experiments with many individual experiment steps, such as many changes in the table position in the xy plane, many changes in the focus position by adjusting the z-drive and / or many exposure cycles with turning on and off the light source and triggering the recording times of the camera, adds up this at a considerable loss of time.

In the microscope control unit 100 according to the invention, the commands in the form of the script commands in real time are now available to the microscope control unit 100 and thus to the microscope system through the script which can be freely configured by the user before the experiment. This leads to a much faster course of the experiment. By providing a script outside the firmware, the user can also integrate any electrically controllable components into his experiment.

Claims

claims

1. microscope control unit (100) with at least one connection (IO1) which can be connected to one or more electrically controllable microscope components (200, 300) or other electrically controllable components, at least one connection parameter of the at least one connection (101) being programmatically configurable,

 wherein at least one script is provided with script instructions on the microscope control unit (100),

 and wherein the at least one port (101) is controllable by means of the script commands.

2. The microscope control unit (100) according to claim 1, wherein the at least one connection parameter can be configured programmatically by means of the script commands.

3. microscope control unit (100) according to claim 1 or 2, wherein the at least one connection parameter comprises at least one parameter that configures the at least one terminal as an input or output and / or as an analog or digital connection and / or as a current or voltage interface.

4. microscope control unit (100) according to any one of the preceding claims, wherein the at least one connection parameter comprises a communication protocol and / or a transmission rate and / or a signal amplitude.

5. microscope control unit (100) according to any one of the preceding claims, wherein the at least one terminal (101) is optionally configurable as an analog input or as a digital input and / or wherein the at least one terminal (101) comprises an analog input and / or wherein the at least one terminal (101) comprises a digital input.

6. microscope control unit (100) according to any one of the preceding claims, wherein the at least one terminal (101) is optionally configurable as an analog output or digital output and / or wherein the at least one terminal (101) comprises an analog output and / or wherein the at least a terminal (101) comprises a digital output.

7. microscope control unit (100) according to any one of the preceding claims, which is adapted to control by means of the script commands via the at least one terminal (101) any combination of one or more electrically controllable microscope components (200, 300) or other electrically controllable components.

8. The microscope control unit (100) according to one of the preceding claims, to which there is a script command set, wherein from a user, the script commands of the at least one script from the script command set are selectable and their sequence can be specified in the script.

9. microscope control unit (100) according to claim 8, which is adapted to be connected to a user interface data transmitting over which of the user the script commands of the at least one script from the script command set are selectable and their sequence can be specified in the script.

10. The microscope control unit (100) according to claim 9, wherein the user interface as a hardware-based input unit of a programmer (10) or is designed as a user interface of a running on a separate processing unit user program.

11. microscope control unit (100) according to one of the preceding claims che, in which the script as a text file on the microscope control unit (100) is transferable.

12. microscope control unit (100) according to any one of the preceding claims, which is associated with a control program with an interpreter for the script, which converts the script commands in functions of the at least one terminal (101).

13. The microscope control unit (100) according to claim 12, wherein the control program is stored in the microscope control unit (100) or in an assembly outside the microscope control unit (100).

14. A microscope control unit (100) according to claim 12 or 13, comprising an electronics unit and an associated control program comprising an interpreter for the script.

15. A microscope control unit (100) according to any one of the preceding claims, wherein the script commands are implemented as real-time commands.

16. microscope control unit (100) according to one of the preceding claims, in which by means of the script commands channel types for the at least one connection (101) can be specified.

17. microscope control unit (100) according to any one of the preceding claims, in which by means of the script commands at least one variable and / or at least one command and / or at least one script and / or at least one function block is provided by means of channels.

18. Microscope system

 with a microscope control unit (100) according to one of the preceding claims, which is connected in a data-transmitting manner with one or more electrically controllable microscope components (200, 300) or other electrically controllable components.

19. A method for operating a microscope control unit (100) with at least one connection (10), which can be connected to one or more electrically controllable microscope components (200, 300) or other electrically controllable components,

 wherein at least one script is stored with script commands on the microscope control unit (100),

 wherein at least one connection parameter of the at least one connection is program-technically configured.

20. The method of claim 19, wherein a microscope control unit (100) is operated according to one of claims 2 to 17.