WO2017009406A1 - Haptic remote controller - Google Patents

Abstract

The invention relates to a remote controller (1) for a real or virtual moving object (5), comprising: at least one operating element (10) which is for generating first control signals (S1) relating to a movement of the object (5), and which can be manually adjusted between multiple adjustment positions, wherein an adjustment region (V) defines limits of the the manual adjustability of the at least one operating element (10); at least one actuator (11) designed and configured to adjust the at least one operating element (10) between the adjustment positions; and at least one control unit (13) designed and configured for the open-loop control of the at least one actuator (11), and, by means of the at least one actuator, for the closed-loop control of the adjustment position of the at least one operating element (10) in relation to a desired adjustment position. In this way, the adjustment region (V) defines limits of the possible desired adjustment positions.

Description

 Haptic remote control

description

The invention relates to a remote control for a real or virtual moving object.

Such a remote control for a real or virtual moving object comprises at least one operating element, which is manually adjustable for generating first control signals, which relate to a movement of the object, between a plurality of adjustment positions. In this case, an adjustment range defines limits of the manual adjustability of the at least one operating element. Such a remote control further comprises at least one actuator, which is designed and configured to adjust the at least one operating element between the adjustment positions of the adjustment.

Such a remote control may be, for example, a model aircraft remote control. It may also be, for example, a remote control for a model car or a model boat. In this case, the exemplified movable objects -. Model airplane, model car or model boat - real or virtual objects.

For example, virtual moving objects play a role in computer-implemented model simulations for gaming or training purposes. The movement of the virtual object can be tracked on a screen and controlled by means of a remote control connected to the computer. The remote control may be provided with a force feedback function, as known from man-bearing aviation in the context of fly-by-wire controls. In this case, an operating element of the remote control is acted upon by an actuator with forces and / or torques to give an operator the impression of physical counter-forces, which take effect on certain tax movements or flight conditions to convey. In this way, for example, a flight simulation or a car racing game can be experienced as more realistic. A joystick with the force feedback function described is known, for example, from US Pat. No. 6,429,849 B1. Accordingly, a motor is provided on a joystick, which is controlled by a controller, to act on the joystick along two axes of rotation with corresponding torques. With known remote controls of the type described, an operator may be given the impression of opposing forces and counter torques, but they do not allow to automatically adjust an operating element in such a way that the moving object would actually be controllable with these movements. However, this may be desirable, for example, in the training of model learner students to teach corrective remote control movements of a model flying instructor or at an air show for sympathizing with the remote control movements of a model flying artist by the audience.

The object of the present invention is to provide a remote control for a real or virtual moving object, which allows a haptic switching of remote control movements of an entity, for example from a remote control of a model flying instructor, to a remote control operator.

This object is achieved by a remote control with the features of claim 1.

Accordingly, at least one control unit is provided on a generic remote control further, which is designed and configured to control the at least one actuator and to regulate the adjustment of the at least one control element with respect to a desired adjustment by means of at least one actuator. The adjustment range defines limits of the possible setpoint adjustment positions.

The invention is based on the idea that remote control movements can be haptically conveyed when all adjustment positions in which a control element is manually adjustable, also automatically, ie by the actuator, are specifically approached. By means of the control unit can, for example, a desired adjustment of the Operating element are approached, which corresponds to a current adjustment position of a control element of a model flying instructor remote control. For the operator, for example, a model student, there is thus the possibility of sympathizing with the remote control movements of the flight instructor at the same time as observing the real model airplane in order to memorize the required joystick movements.

It is also conceivable to send in a flight simulator of a simulated model aircraft control signals back to the remote control and implement there in movements of the joysticks. For example, pre-recorded flight sequences can be played and the appropriate joystick movements can be tangibly conveyed to a training operator.

For example, the moving object may be an unmanned land vehicle, watercraft and / or aircraft. For example, the object may be a remotely controllable model vehicle for land, sea, and / or air operation, particularly a remotely controllable model airplane or a model remote controlled helicopter. The remote control of such models generally requires a comparatively complex training, in which the haptic switching of remote control movements of a model flying instructor according to the invention to a model student can be used particularly advantageously.

According to a further aspect of the invention, a remote control dummy is provided in the manner of a model remote control. The remote control dummy has at least two control elements, which are designed as control sticks and are adjustable in accordance with the adjustment positions of the control stick of a model remote control between a plurality of adjustment positions within an adjustment range. For example, the joysticks may be pivotable about at least two axes. The remote control dummy further comprises at least one actuator per control element, wherein the at least one actuator is designed and configured to adjust the respective control between the adjustment of the adjustment, and at least one control unit which is designed and configured to control the at least one actuator per control and to regulate the adjustment position of the respective operating element with respect to a desired adjustment position by means of the at least one actuator. The adjustment range defines limits of the possible setpoint Adjustment positions. With such a remote control dummy, for example, a model flying student or a spectator of a model flying show haptic feel joystick movements of a flight instructor or model flying artist.

The possible adjustment positions of a control element of the remote control or the remote control dummy can be distributed continuously in the adjustment range. For example, the control element may be a joystick which can be continuously swiveled about several axes or a continuously adjustable slider. Especially with such continuously adjustable controls complex control movements by means of a remote control according to the invention can be particularly catchy mediated by haptic Nachfühlen.

It can also be provided that a control element of a remote control or a remote control dummy is designed to be adjusted under superimposed effects of the actuator on the one hand and a manual operation by the operator on the other hand between the adjustment positions. By this it is meant that such a superimposed actuation of the operating element according to the construction of the operating element and the actuator is also provided and can not be effected only by "brute force" during the manual actuation, for example, a control stick on a shaft of an electric motor , which forms an actuator, be attached, wherein the shaft of the electric motor is designed to be smooth and rotatable from the outside.In this case, the actuator does not constitute a mechanical design inhibition for a manual adjustment of the operating element.

In a development, the control unit of the remote control or the remote control dummy is designed to limit the force and / or the torque with which or which the actuator acts on the operating element. In particular, limits of the force and / or the torque can be variably adjustable. In this way, the action of the actuator can superimpose a manual operation of the control element more or less. For example, an adjustment device for upper limits of the force and / or the torque of the actuator can be provided on the remote control. An operator then has z. Example, the possibility of the limits of the force and / or the torque of the actuator within an interval from zero to a respective maximum upper limit for the force and / or to select the torque. If a low upper limit is set by the operator, he essentially actuates the operating element manually manually, whereby only slight haptic corrections are provided by the relatively low forces and / or torques of the actuator. If, on the other hand, a relatively high upper limit is set, then the operator can essentially leave the control to the actuator and only largely passively sense its control movements of the operating element.

In one variant, the remote control or the remote control dummy additionally comprises a sensor unit for detecting the adjustment position in which a control element is located, and for translating the detected adjustment position into second control signals, and a signal output for outputting the second control signals. By way of example, a current adjustment position of the operating element can be detected by means of potentiometers or optical and / or magnetic sensors arranged on the operating element. As part of the sensor unit measuring signals, such as the potentiometer, can be encoded in the second control signals. Via the signal output of the remote control, the second control signals can be output externally. The signal output can z. B. comprise a radio transmission unit for the second control signals. However, it is also conceivable that the signal output has a socket for a wired output of the control signals.

For example, the operator may be a model instructor, and the detected by means of the sensor unit adjustment positions of one or more controls on his remote control can be transmitted as a second control signals to another remote control according to the invention of a model student. The control unit of the remote control of the model pupil can control a corresponding control element with respect to a desired adjustment position, wherein the desired adjustment position z. B. a transmitted by means of the second control signals current adjustment position of a control element of the remote control of the model flying instructor can correspond.

According to a further aspect of the invention, a system is provided for haptic switching of remote control movements. The system has at least one haptic control unit which comprises a remote control according to the invention and / or a remote control dummy according to the invention. In this case, the remote control dummy comprises at least one actuator and a control unit, as they has been described above with reference to a remote control according to the invention, but is not designed to generate the first control signals related to the movement of an object. Furthermore, the system comprises at least one instance for providing second control signals, from which a desired adjustment position of the at least one operating element of the haptic control device can be derived. In this case, the second control signals from the at least one instance can be transmitted to the control unit of the at least one haptic operating device.

For example, the instance for providing second control signals may include a remote control according to the invention with a sensor unit with which an adjustment position of a control element can be detected and translated into second control signals. It may be provided that the second control signals are output via a signal output of the remote control and transmitted, for example by radio or by wire, to one or more haptic control devices of the system. From the transmitted second control signals, a desired adjustment position of one or more operating elements of the at least one haptic operating device can be derived, with respect to which the control unit of the respective haptic operating device can control the operating element. The radio, which represents the instance, z. B. be served by a model instructor. Accordingly, one or more haptic operator devices that can receive the second control signals from the instance, for. B. operated by model learners.

This aspect of the invention is based on the idea that with the system according to the invention, remote control movements of an entity, for example a model flight instructor or model simulator, can be haptically communicated to one or more operators of one or more haptic operator devices, for example in the manner of a model flight remote control. By means of the system, for example, a model student can be corrected in his remote control movements by a model instructor. It is also conceivable that at the same time several operators of remote controls or remote control dummies, which realize a haptic control unit, purely passive by haptic tracking the remote control movements of a model flying instructor or example of a model flying artist follow in a model air show.

It is also within the scope of the invention that the instance comprises a computer and / or a server. In particular, the entity may provide the second Control signals a model simulator, which is executed on the computer and / or the server to be. Thus, for example, remote control movements relating to certain movement sequences of a virtual object in the context of the model simulator stored in a database of the computer and / or server and as second control signals to a connected to the computer and / or server remote control or Fernsteuerungsattrappe be transmitted. In this case, the second control signals, for example, within a network such. B. be deposited on the Internet. It is also conceivable that the second control signals are generated by a remote control according to the invention with a sensor unit and transmitted via the Internet to at least one haptic control unit. The transmission can be done directly or delayed, ie by storing the control signals in a database for later retrieval.

It is also within the scope of the invention that the haptic control device comprises a remote control according to the invention for a real movable object, wherein the object has a telemetry unit for acquiring measured data. Within the scope of the system, the telemetry unit can form an instance (or a part thereof), wherein the second control signals are derived from the measured data of the telemetry unit. For example, aircraft models according to the prior art already have the ability to send current operating data such as flight altitude, speed, rotor speed, battery capacity, etc. via such a telemetry unit back to a remote control. In previous solutions, these data are displayed to the operator via the remote control visually or by voice. Furthermore, it is known to provide a haptic feedback on the remote control when an error situation occurs, wherein, for example, a vibration of a joystick can indicate to the operator the presence of the error situation.

With the telemetry unit as an instance in a system according to the invention can now with the second control signals sensor-based control information, for example, for automatically canceling pitch at speed drop of the rotor of a model helicopter, to transmit the remote control as a haptic control unit. Because of these second control signals, for example, a control element for adjusting the pitch can be adjusted automatically, this automatic emergency correction being conveyed tangibly to the operator. In this case, an adjustment position of the operating element is only automatically by the control unit and the actuator of the remote control approached when the applied by the operator manual holding or holding force is too low to counteract the actuating force of the actuator or when the operator has completely released the control. In any case, the direction of the automatic correction by the telemetry unit is noticeable to the operator.

The object is also achieved by a method for the haptic switching of remote control movements, which uses a system according to the invention.

Accordingly, in a first step, the second control signals are provided by the at least one instance, wherein the second control signals relate to a desired adjustment position of the at least one operating element of the haptic control device. For this purpose, for example, in a remote control according to the invention with a sensor unit detects the adjustment of one or more controls, then translated into second control signals and output to the output signal. Alternatively, the second control signals may also be provided by a computer and / or a server running a model simulator. It is also conceivable that the second control signals are provided by a computer and / or a server on which they are stored within a database. In a second step, the second control signals are transmitted from the instance to the haptic operating device. The transmission of the second control signals can for example be done by radio from a remote control of a model flying instructor to the remote control of a model pupil. However, the transmission may also be wired, for example, by cable from a computer to a remote control dummy connected thereto.

In a third step, the adjustment position of the at least one operating element of the haptic control device is regulated as a function of the second control signals. In this case, the control takes place by means of the control unit and the at least one actuator of the haptic control unit. For example, a joystick on the remote control of a model learner can be controlled to an adjustment position corresponding to an adjustment position of a joystick on the remote control of a model flying instructor representing the instance. The controls of the instance and the haptic control device are designed such that it is a substantially unique Figure between the adjustment positions of the control element of the instance on the one hand and the operating element of the haptic control unit on the other hand.

In a variant of the method, at least two remote controls according to the invention, each having a sensor unit, are used. In this case, on the one hand, a first remote control is used as a first instance for a second remote control as a first haptic operating element, wherein the desired adjustment position of the at least one operating element of the second remote control corresponds to an adjustment position of a corresponding operating element of the first remote control. On the other hand, in turn, the second remote control is used as a second instance for the first remote control as a second haptic control unit, wherein the desired adjustment position of the at least one control element of the first remote control corresponds to an adjustment position of a corresponding control element of the second remote control. For example, a remote control of a model student on the one hand receive second control signals from a remote control of a model flying instructor and thus sense its remote control movements on a joystick, and vice versa, the model instructor with its remote control second control signals from the model student's remote control receive, so the model instructor remote control movements of the model pupil can feel haptic.

It can be further provided in a method according to the invention that the at least one control element is acted upon by the at least one actuator for adjusting the adjustment position with an even greater force and / or torque, the farther the adjustment position of the at least one operating element of the deviates from the respective desired adjustment position. For example, the force and / or the torque may depend substantially linearly on the deviation. In this way, a, e.g. elastic, haptic coupling between a control element of the first remote control (for example, the model flying instructor) and a control element of the second remote control (for example, the model pupil) can be realized. Such a haptic coupling is analogous to a coupling of the control horns of a pilot and a copilot, as it is known from man-carrying aviation to understand.

In a development, it can be provided that in the case of a deviation between the adjustment position of the at least one operating element and the respective desired Adjustment of the at least one operating element is acted upon by the at least one actuator with a greater force and / or with a greater torque, the greater a coupling strength is selected for the at least one control element. In this case, the coupling strength is set on the at least one haptic operating device and / or on the at least one instance.

For example, it may be provided that a coupling strength of a haptic coupling between a first remote control and a second remote control by means of the control units is set variably as needed. The coupling strength can be set, for example, in a range from zero to a maximum coupling strength, wherein the maximum coupling strength z. B. (depending on the power of the actuator) may correspond to a substantially rigid coupling between the controls of the first remote control and the second remote control. It can be done adjusting the coupling strength for the respective remote control on the remote control itself. Alternatively or additionally, the coupling strength for both remote controls can be set on one of the remote controls.

The idea underlying the invention will be explained in more detail with reference to the embodiments illustrated in the figures. Show it:

Fig. 1A is a schematic view of a remote control in a first variant;

Fig. 1B is a schematic view of a remote control in a second variant; Fig. 1C is a schematic view of a remote control dummy;

2A is a schematic view of an operating element with an actuator in a first variant;

2B is a schematic view of an operating element with an actuator in a second variant;

2C is a schematic view of an operating element with an actuator in a third variant; Remote control movements in a first variant;

Fig. 4 is a schematic view of a system for the haptic switching of

 Remote control movements in a second variant;

Fig. 5 is a schematic view of a system for the haptic exchange of

 Remote control movements in a third variant; and FIG. 6 is a schematic view of a haptic exchange system of FIG

 Remote control movements in a fourth variant.

Figures 1 A and 1 B show a remote control 1 for a real or virtual moving object 5 in a first and second variant. For example, the remote controls 1 shown may be for a model airplane or a model helicopter. The remote controls 1 but also z. B. for remote control of other unmanned land vehicles, watercraft and / or aircraft and be provided. The illustrated remote controls 1 have controls 10, which are exemplified here as two joysticks 10 in the manner of a model remote control. An operator B of the remote control 1 can manually adjust the operating elements 10 between a plurality of possible adjustment positions (the manual action on the operating elements is symbolized here by a thin arrow from the operator B to the operating elements 10). In this case, the control elements 10 and possibly a microcontroller generate first control signals S1 for controlling the movement of the object 5 and apply them to a first signal output 16. The first signal output 16 may, for example, a transmitting unit, for. B. the high-frequency part of a conventional model remote control. In other embodiments, the first signal output 16 may also include a cable socket for hard-wired output of the first control signals S1.

An adjustment range V defines limits of the manual adjustability of the operating elements 10. In the present case, the control sticks can be adjusted continuously within a certain radius (corresponding to the respective outer dashed circles around the operating element 10 of FIGS. 1A-1C), the radius defining the adjustment range V. , is designed to apply the control elements 10 with a force F and / or torque and consequently to adjust it within the adjustment range V. For example, an electromechanical unit may be provided as an actuator 1 1 on one or more controls 10. Examples of this are explained below with reference to FIGS. 2A to 2C.

The automatic adjustment of a control element 10 by the actuator 1 1 is haptic perceptible to the operator on the control element 10, i. palpable. This haptic perception of the automatic adjustment movements of the operating elements 10 is symbolized in FIGS. 1 A-1 C with a thick arrow from the operating elements 10 to the operator B.

A control unit 13 of the remote control 1 is designed and configured to control the actuator 1 1 and thereby to regulate the adjustment positions of the operating elements 10 with respect to a desired adjustment position. In this case, the adjustment range V defines limits of the possible setpoint adjustment positions, that is, any adjustment position within the adjustment range V can be approached by means of the control unit 13. The control unit 13 may comprise, for example, a microcontroller. For example, the control unit 13 may be designed to transmit both force-related control signals SF and position-related control signals SP to the actuator 11 as part of the regulation of the adjustment position of a control element 10. In this case, the force-related control signals SF should possibly also be understood as control signals which relate to a torque of the actuator 11. Under the scheme z. B. a feedback channel SR be provided, via which measurement signals with respect to a current adjustment position of the control element 10 back to a microcontroller of the control unit can be communicated.

In the exemplary embodiment, the control unit 13 receives second control signals S2 from a signal input 12 of the remote control 1. In this case, the control unit 13 can derive from the second control signals S2 setpoint adjustment positions for the operating elements 10 and transmit corresponding control signals SF, SP for regulating the adjustment positions of a control element 10 to the actuator 11. The second control signals S2 can be transmitted, for example, from an instance 32 outside the remote control 1 to the signal input 12. In such a for the haptic communication of remote control movements.

The instance 32 which provides the second control signals S2 may, for example, be a further remote control 1 according to the invention, which is shown schematically in FIG. 1B. Accordingly, a sensor unit 15 for detecting the adjustment position, in which a control element 10 is located, as well as for translating the detected adjustment position into second control signals S2 is provided on a remote control 1, as has been explained with reference to FIG. 1A. For example, the sensor unit 15 may comprise one or more potentiometers, magnetic sensors and / or optical sensors which can detect a current adjustment position of the operating elements 10. It is also conceivable that the detected adjustment positions are used at the same time for the generation of the first control signals S1. The translation of the detected adjustment positions in the second control signals S2 can, for. B. be made by a microcontroller of the sensor unit 15.

The second control signals S2 can be output via a second signal output 14 which is provided on the remote control 1 according to FIG. 1B. Of the second signal output 14, the second control signals S2 wirelessly or wired to a haptic control unit 31, such as a remote control 1 of Figure 1 A, can be transmitted.

The second signal output 14 may, for example, a cable socket or a transmitting unit, for. B. a high frequency part include. For example, in a remote control 1 for a model airplane 5 for the transmission of the second control signals S2, a second radio link independent of a radio transmission of the first control signals S1 to a model airplane 5 can be provided. With the second control signals S2, channel values for the individual servos of the model airplane 5, which are not already converted by a controller, must be used, for example. the original adjustment positions of the joystick 10 are transmitted.

Insofar as the second signal output 14 can comprise, for example, a transmitting unit for the second control signals in the form of a high-frequency part and is thus provided for translating the adjustment positions detected by the sensor unit 15 into second control signals S2 (as radio signals), the second signal output 14 can also be used as part of Sensor unit 15 are understood or have with this common components. Depending on the transmitted second control signals S2, the adjustment position of at least one operating element 10 of the haptic control device 31 can then be regulated. In this case, a further remote control 1 according to the figure 1 B in the context of a system according to the invention 3 serve as a haptic control unit, which receives, for example, on the one hand via the signal input 12 second control signals S2 and on the other hand (other) second control signals S2 via the second signal output 14 and to another haptic control unit 31 transmitted.

The haptic control unit 31 can be realized in a variant by a remote control dummy 7 according to the figure 1 C. This differs from a remote control 1 according to FIG. 1A in that it is not designed to generate first control signals S1 for remote control of a mobile object 5. Such a remote control dummy 7 can be provided, for example, for training purposes for a model student pilot as operator B, who can thus sense the remote control movements of a model flying instructor.

It can also be provided that the controls 10 on the remote control dummy 7 of Figure 1 C are not manually adjustable, but only automatically by the at least one actuator 1 1.

In contrast, in remote controls 1 according to Figures 1 A and 1 B, the control element 10 on the one hand and a manual operation by the operator B on the other hand be adjustable under the superimposed effects of the actuator 1 1. In this case, the force F and / or the torque M with which the actuator 1 1 acts on the operating element 10 can be limited by means of the control unit 13. In one variant, the limits of the force 1 1 and / or the torque can be variably adjusted by means of the control unit 13, for example via a rotary knob.

FIGS. 2A to 2C show a schematic view of various embodiments of a control element 10 with an actuator 1 1 arranged thereon. The operating element 10 according to FIG. 2A is a joystick which is shown here by way of example only in a single-axis design (ie with only one active plane). The joystick 10 is arranged on a shaft of an electric motor 1 10, which forms part of the actuator 1 1. In this case, the electric motor 1 10 in an advantageous embodiment constructive for a large torque and low speed be formed rotatable. For example, to achieve a corresponding ease, the joystick 10 may be attached directly to the shaft without providing an intermediate gear.

The joystick 10 is in this embodiment under the superimposed effects of manual action by the operator on the one hand and the brought by the electric motor 1 10 on the shaft torque on the other hand over its entire adjustment range V away adjustable. In this case, 10 return springs 1 13 may be provided on the joystick, which move the joystick 10 back to a centering or home position upon removal of the two drive effects.

In the embodiment of Figure 2B is as a control element 1 1, a slider on a spindle 1 1 1 mounted. The spindle 1 1 1 is driven by an electric motor 1 10. About the spindle 1 1 1 applied to the electric motor 1 10, the slider 10 with a force F, whereby the slider 10 along the spindle 1 1 1 is linearly adjustable. This is an example of an arrangement in which a manual operation of the slider 10 from the outside, so by an operator B, difficult or even excluded by design. Such an arrangement can be used, for example, in a remote control dummy 7 according to FIG. 1C. In this case, the slider 10 is the operator B, for example, exclusively for learning suitable sliding positions, for example in the context of complex flight sequences of a model airplane. If the slider 10, as shown in Figure 2C, in contrast, mounted on a belt 1 12, which is driven by an electric motor 1 10, so its adjustment is adjustable both by the electric motor 1 10 as an actuator 1 1 and manually by the operator B. , A design-related mechanical inhibition as in the embodiment of Figure 2B is not present. Preferably, the electric motor 1 10 is designed for a large torque and a low speed and also has a smooth and rotatable shaft from the outside. Such a slider 10 can be used, for example, in a remote control 1 according to FIGS. 1 A or 1 B with which an operator B can remotely control an object 5 at the same time and can additionally experience haptic remote control movements from an instance 32. System 3 according to the invention for the haptic switching of remote control movements, wherein the previously described remote controls 1 and remote control dummy 7 according to Figures 1 A to 1 C can be used as haptic control devices 31.

FIG. 3 schematically shows a system 3 for the haptic switching of remote control movements in a first variant. In the illustrated system 3, a first remote control 1 -1 of a first operator B1 serves as an instance 32, which provides second control signals S2-2 to a second remote control 1 -2 as a haptic control unit 31. In this case, adjustment positions of operating elements 10 of the first remote control 1 -1 are encoded in the second control signals S2-2. The second control signals S2-2 are transmitted, for example, by radio to the second remote control 1-2, and the adjustment positions of operating elements 10 of the second remote control 1-2 are regulated with respect to the desired adjustment positions transmitted with the second control signals S2-2.

Conversely, second control signals S2-1 for the regulation of the adjustment positions of the operating elements 10 of the first remote control 1 -1 can be provided in a very analogous manner by the second remote control. In this way, a mutual coupling of the controls 10 of the first remote control 1 -1 and the second remote control 1 -2 can be realized.

This embodiment is based on the idea, for example, a model learner B2 on the controls 10 of his second remote control 1-2 a haptic feedback, which is generated by a model flying instructor B1 with the first remote control 1 -1, mediate. For this purpose, with the illustrated system 3, in particular a complete image of the operating elements 10 of the first remote control 1 -1 of the model flying instructor B1 can be transmitted haptically to the model learner B2.

The inventive system 3 realizes a coupling between the controls of the first remote control 1 -1 of the model instructor B1 on the one hand and the second remote control 1 -2 of the model learner B2 on the other hand, which is analogous to the coupling of the control horns Pilot and Copilot in the man-carrying aviation to understand. Both pilot and co-pilot can fly the plane, and both can feel what the other one is doing at any time, so they can intervene quickly in the event of problems. In particular, it can be provided that a coupling strength of the coupling by means of the control units 13 is variably adjustable as needed. The coupling strength, for example, be adjustable in a range from zero to a maximum coupling strength, the maximum coupling strength z. B. a substantially rigid coupling between the controls 10 of the first remote control 1 -1 and the second remote control 1 -2 can correspond.

In the exemplary embodiment of FIG. 3, the first remote control 1 -1 of the model flying instructor B1 is radio-coupled to the model airplane 5. Thus, the model instructor B1 has the primary responsibility for properly controlling the model airplane 5.

If the model instructor B1 now moves his joystick 10, then their adjustment positions on the one hand to control the model airplane 5 in a controller in first control signals S1, which z. B. servo signals, charged and sent to the model aircraft 5 via the first signal output 16 (see Figure 1 B). On the other hand, the adjustment positions of the joystick 10 are detected by the sensor unit 15 and sent via the second signal output 14 as second control signals S2-2 to the signal input 12 of the second remote control 1-2 of the model learner B2.

At the second remote control 1-2, the received second control signals S2-2 are converted by the control unit 13 into desired adjustment positions for the control of the control stick 10. The actuator 1 1 is supplied by the control unit 13 with corresponding input signals SP, SF with respect to a force, a torque and / or a position. As a result, the control by the control unit 13 and the actuator 1 1 leads to an electromotive operation of the joystick 10, wherein the joystick 10 without manual influence from outside in their two axes each precisely take that adjustment that an adjustment of the corresponding joystick 10 on the first remote control corresponds to 1 -1. This allows the model learner B2 to track the remote control movements of the model flying instructor B1.

Since the described coupling is realized in both directions, also the model learner B2 can operate the joystick 10 of his second remote control 1-2 manually, their adjustment positions being transmitted in the form of second control signals S2-1 to the first remote control 1 -1 of the model flying instructor B1 , If the against the force F (or a setting torque M) of the actuator 1 1 applies, so take his stick 10, the adjustment of the joystick 10 of the second remote control 1 -2 of the Modellflugschülers B2 a. In this case, the first remote control 1 -1 of the model flying instructor B1 is "remotely controlled" by the model learner B2, whereby the model learner B2 transiently controls the model airplane 5 via the first remote control 1 -1.

In the event that the model learner B2 commits a critical control error, the model instructor B1 can intervene at any time and with his, for the remote control of the model airplane 5 ultimately relevant, control sticks 10 Correct accordingly. In this case, the model instructor B1 must manually overcome the actuating force F of the actuator 1 1, it being possible to provide that he has a maximum actuating force and / or a maximum torque of the actuator 1 1 via another operating element of the first remote control 1 -1 (eg. via a rotary potentiometer or a slider) can set variably.

As a result of this manual intervention by the model instructor B1, the actuator 1 1 of the first remote control 1 -1 can not approach the predetermined by the model learner B2 adjustment position of the joystick 10, and the joystick 10 of the first remote control 1 -1 reach the required for the rescue of the model airplane 5 Adjustment positions according to the specifications of the model flying instructor B1.

The model learner B2 feels while caused by the correction of the model flying instructor B1 force F of its actuator 1 1 via the joystick 10 of its second remote control 1-2. This gives the model learner B2 an immediate feedback on his tax error and especially feels exactly the desired correct position of the joystick 10. It also has the model learner B2, the possibility of his second remote control 1-2 a maximum force and / or maximum torque of the Adjust actuator 1 1. Depending on training progress and application (eg, slow glider, fast and hard aerobatics, helicopter 3-D flight, etc.), different settings may make sense. If the model learner B2 ignores the correction of the model flying instructor B1 and acts with its manual force against the actuator 1 1, this has no consequences for the model airplane 5, since for the remote control of the model airplane 5 yes Adjustment positions of the joysticks of the second remote control 1 -2 are thus ignored by the model airplane 5 in this case. FIG. 4 shows a second variant of a system 3 according to the invention for the haptic switching of remote control movements. In this case, a haptic control device 31 of a second operator B2 is connected to a computer 320, on which a model simulator is executed. The haptic control device 31 can be, for example, a remote control 1 according to FIGS. 1A-1B or a remote control dummy 7 according to FIG. 1C. The model simulator simulates the movement of a virtual moving object 5, for example a helicopter 5. In FIG. 4, on the screen of the computer 320, in addition to the virtual object 5, a virtual remote control can be seen, as often occurs in model simulators. As part of the system 3, the computer 320 represents an instance 32 for the haptic control device 31 in that it provides second control signals S2 for regulating the adjustment positions of the control elements 10 via a signal input 12 of the haptic control device 31. In a conventional mode of operation of a model simulator, the second operator B2 adjusts the joysticks 10 of his remote control 1. The adjustment positions of the joystick 10 are transmitted via a first signal output 16 as first control signals S1 to the computer 320. As part of the model simulator, the first control signals S1 are converted into corresponding adjustment positions of the virtual remote control mapped on the monitor and into a control of the movement of the virtual object 5.

The system 3 according to the invention enables a new operating mode, in which the second operator B2 enters a flight sequence (for example a particularly difficult maneuver) already previously entered by a pilot pilot and third operator B3 and stored in a database 322 of the computer 320 into the model simulator can load. In this case, the uploading of the flight sequence can also take place, for example, via an internet platform. When the second operator B2 starts the loaded flight sequence at the model simulator level, the joysticks 10 of his haptic control device 31 are moved precisely according to the stored specifications of the flight sequence. This can become a realistic experience, especially in conjunction with other stored parameters, such as a model type, simulated wind conditions, etc. stored flight sequence is sent from the virtual remote control in the form of second control signals S2 to the signal input 12 of the haptic control unit 31 and leads there via the control unit 13 to control the actuator 1 1 and ultimately the controls 10. Thus, the second operator B2, the correct deflection the joystick 10 for the difficult flight sequence in addition to the visual perception of the virtual remote control on the joysticks 10 haptically follow. Also conceivable are hybrid forms of the two described modes of operation, in which the second operator B2 on the one hand has the option of manually controlling the virtual object 5 itself, but on the other hand is still gently guided via the haptic feedback of the virtual remote control. Thus, due to the flight sequence database 322, the virtual remote control knows the optimal control flow and can compare it with the manual remote control movements of the second operator B2. If the deviations from the optimal remote control movements become too large, a corresponding opposing force F and / or a corresponding counter-torque M can be generated on the control stick 10 of the haptic control device 31 with the actuator 1 1.

With regard to visual feedback, a so-called split-screen approach is also conceivable, for example the virtual object 5 which is optimally controlled by the virtual remote control is shown in the left half of the screen and the virtual object 5 manually controlled by the second operator B2 on the right half of the screen In addition to the deviations in the movements of the two virtual objects 5, the deviations of the adjustment positions of the joystick 10 of the virtual remote control on the one hand and the haptic control device 31 on the other hand can also be graphically animated and evaluated at the end of the simulated flight. An integral of the deviations of the adjustment positions over the duration of the simulated flight would be a first clue for the execution quality and the learning success of the model learner B2.

According to a further variant of the embodiment of FIG. 4, two model simulations with their respective operators (for example a first operator B1 as a model instructor and a second operator B2 as a model learner) can be coupled live and time synchronously via the Internet 321. This model flight instructor / model learner scenario is analogous to that with reference to FIG. 3 Weather independence of the two operators B1, B2.

The two haptic control devices 31 are in this case not connected to each other by radio or cable but each via a model simulator, which is executed on a computer 320, wherein the computer 320 are in turn coupled to each other via the Internet 321. Although physically it is two different remote controls 1 of the first operator B1 and the second operator B2 remains through the coupling only a logical virtual remote control and a logical virtual object 5, which both operators B1, B2 can see and control remotely.

The operator B1 can dominantly control the virtual remote control with his haptic control device 31 as a model instructor, which in turn leads to the control of the virtual object 5. For example, by headset communication, the first operator B1 can give the second operator B2 the command to take over the remote control (just like pilot and co-pilot communicate in the cockpit of a man-carrying machine via helmet microphone and headphones). The second operator B2 can then control the single logical virtual remote control and, moreover, the virtual object 5. The adjustment positions of the joysticks of the virtual remote control via the Internet 321 are sent to the haptic control unit 31 of the first operator B1 and cause there a corresponding deflection of the joystick 10th

FIG. 5 shows a further variant of the system 3 according to the invention for the haptic switching of remote control movements. At the same time, many spectators (both real and virtual via the Internet 321) can haptically simulate a model flight demonstration by a competition or show pilot and, accordingly, experience it "live".

A show pilot controls in this embodiment as a first operator B1 a real model airplane 5. The joystick movements and thus required for remote control of the model airplane 5 control signals S2 are transferred to haptic control units 31 real, present at the flight event viewer B2. In response to the second control signals S2, the joysticks 10 of the haptic control devices 31, which can be implemented, for example, as remote controls 1 or remote control dummies 7 are moved, whereby the spectator B2 a Nachfühlen the show flight is enabled. In addition to the real on-site viewers B2, the second control signal S2 of the show or competition pilot can also be transmitted via an Internet platform 321 to an interested global community. Virtual viewers B2 can then, for example, by means of a software to be installed on their home PC 320 and a haptic control unit 31 to be connected to the home PC 320, experience and experience the show flight "live" or else with a time delay In this case, they must be transmitted in a time-synchronized manner, for example by means of a streaming method, by the Internet platform 321. The software to be installed on the home PC 320 then decodes the input signals S2 necessary for controlling the haptic control device 31 from the stream

A fourth variant of a system 3 according to the invention is shown schematically in FIG. In this case, an operator B controls with a remote control 1, which realizes a haptic control unit 31, a real remotely controllable object 5, such as a model helicopter. At the object 5, a telemetry unit 51 is arranged, which with a telemetry sensor 510 current operating data such as altitude, airspeed, rotor speed, battery capacity, etc. can capture and spark via a telemetry transmitter 51 1 to the remote control 1 of the operator B. Conventionally, such telemetry data is communicated to an operator B visually or by voice.

In the exemplary embodiment shown, it is provided that the remote control 1 of the operator B and the telemetry unit 51 of the object 5 realize a system 3 according to the invention, the object 5 with the telemetry unit 51 representing an instance 32 for the remote control 1 as a haptic control unit 31.

The operator B controls the remotely controllable object 5 via the joystick 10 of his remote control. 1 In this case, the first control signals S1 are transmitted via the first signal output 16 to a receiver 52 of the remotely controllable object 5. As a result, the first control signals S1 are converted into movements of individual servos (rowing machines) 53 of the remotely controllable object 5, which ultimately physically control the object 5.

Based on certain flight conditions or flight conditions (for example, too low a rotor speed, too low height, too low battery capacity, etc.), the telemetry sensor 510 can alarm and cause the telemetry transmitter 51 1, second control signals S2 to the signal input 12 of the haptic control unit 31 send, or to bring joystick 10 in certain adjustment positions. For example, another rotor speed of a model helicopter 5 can be automatically selected in this way with a flight condition switch 10. In the case of a model airplane 5 z. B. an impending stall ("stall" due to low Anströmgeschwindigkeit or too high angle of attack of a wing) cause a saving "pressing" the elevator stick.

In this case, the operator B does not have to stand by and watch an automatic stick position is only approached by the setting unit 1 1 if he does not apply enough manual holding forces or holding torques to hold against an adjustable maximum force or an adjustable maximum torque of the actuator 1 1 can. In any case, the operator B can feel the default direction of automatic correction by the telemetry unit 51 of the remotely controllable object 5.

A further exemplary embodiment of the system 3 according to the invention is conceivable in connection with a multicopter drone which autonomously departs GPS-predefined positions (so-called "waypoints".) If an operator B starts such an autonomous flight mode, the system 3 according to the invention can be used Flight control of the multicopter drone 5 calculated control pulses (to reach the waypoints) are sent via a telemetry transmitter 51 1 of the multicopter drone 5 to a haptic control unit 31 of the operator B, so that the joysticks 10 of the haptic control unit 31 are controlled as in an autopilot It is also a scenario conceivable in which no operation of a switch is required to leave the autopilot mode, but the operator B, for example, in an emergency, only has to resort to the joystick 10 to regain control of the multicopter drone 5. A deviation of the V Creation positions of the joystick 10 of the haptic control unit 31 of the calculated by the Flight Computer optimal adjustment positions can be used as an indicator for leaving the autopilot mode.

According to a further embodiment, in a remote control 1 according to the invention by the provided control unit 13 in conjunction with the actuator 1 1, a manual operation of a joystick 10 for performing precise joysticks movements ("stickmoves") are supported and facilitated. Performing specific embroidery moves by an operator B will counteract unwanted effects. This includes a change in the direction of action of a mechanical restoring force when passing through the centering position (ie the position that the control stick takes after release of the control stick 10). Furthermore, the four quadrant operating surfaces of a conventional joystick 10 generally have different return forces compared to the orthogonal control axes. Thus, movement along the main axes ("up", "down", "left", "right") is easier for an operator than a diagonal movement. The reason for this is the number and characteristics of each participating return springs 1 13. Therefore, for example, it is very difficult to describe a clean circular path with the joystick.

In a remote control 1 erfindungsbemäßen actuators 1 1 can superimpose the characteristics of the return springs to individual specifications. Possible is z. B., each position of the joystick to specify a value for a desired restoring force F in the direction of a freely selectable centering point. If, for example, the points of a circular path around the central centering point uniformly have the restoring force zero in the sequence, it is possible to move the control stick 10 on this restoring forceless circular path within the adjustment range V without much practice.

Basically, the mechanical return springs 1 13 also completely by the control unit 13 and the actuator 1 1, z. B. electromotive, replicated and consequently be saved in the construction of a remote control 1. However, it may be advantageous for safety reasons, yet maintain mechanical return springs 1 13, so that in case of failure of an actuator 1 1 still takes place centering of the joystick 10 by mechanical means.

Furthermore, for example, the generation of an equal restoring force F in all directions is possible. In addition, an undesirable damped oscillation of the joystick 10 around the centering position when suddenly released from a wide deflection can be avoided. In summary, the effect and properties of a joystick 10 can be modified by means of the control unit 13 and the actuator 1 1 depending on the situation and condition. Remote control

 -1 First remote control -2 Second remote control 0 Control element

 1 actuator

 10 engine

 1 1 spindle

 12 straps

 13 return spring

 2 signal input

 3 Control unit 4 Second signal output 5 Sensor unit

 16 First signal output

 system

 1 Haptic control unit 2 instance

 20 computers

 21 server / internet 22 database

 5 object

 51 telemetry unit

510 telemetry sensor

51 1 telemetry transmitter

52 recipients

 53 servo

 7 remote control dummy

B operator

 B1 First operator

B2 Second operator

B3 Third operator

F force

 M torque

 S1 First control signals

S2 Second control signals S2-2 Second control signals for the second remote control

SF force-related control signals

 SP Position-related control signals

 SR feedback channel

 V adjustment range

Claims

Remote control (1) for a real or virtual moving object (5), with

 - At least one control element (10), which for adjusting first control signals (S1), which relate to a movement of the object (5) is manually adjustable between a plurality of adjustment positions, wherein an adjustment range (V) limits the manual adjustability of the at least one operating element (10) defines

 - At least one actuator (1 1), which is designed and arranged to adjust the at least one operating element (10) between the adjustment positions, and

 - At least one control unit (13) which is designed and arranged to control the at least one actuator (1 1) and by means of the at least one actuator (1 1) to control the adjustment of the at least one operating element (10) with respect to a desired adjustment position , wherein the adjustment range (V) defines limits of the possible desired adjustment positions.

Remote control (1) according to claim 1, characterized in that the at least one operating element (10) under superimposed effects of the at least one actuator (1 1) on the one hand and a manual operation on the other hand between the adjustment positions is adjustable.

Remote control (1) according to claim 1 or 2, characterized in that the actuator (1 1) is designed and set up, the at least one operating element (10) for adjusting the adjustment position with a force (F) and / or torque (M) to apply, wherein limits of the force (F) and / or the torque (M) by means of the at least one control unit (13) are variably adjustable.

Remote control (1) according to at least one of claims 1 to 3, characterized in that the adjustment positions of the at least one operating element (10) in the adjustment range (V) are distributed continuously.

Remote control (1) according to at least one of the preceding claims, characterized in that the object (5) is a real unmanned land vehicle, watercraft and / or aircraft. characterized in that the object (5) is a real remote controlled model vehicle for land, sea and / or air operation, in particular a remotely controllable model airplane or a model remote controlled helicopter.

Remote control (1) according to at least one of the preceding claims, characterized by

 - A sensor unit (15) for detecting the adjustment position, in which the at least one operating element (10) is located, and for translating the detected adjustment position into second control signals (S2, S2-1, S2-2), and

- A second signal output (14) for outputting the second control signals (S2, S2-1, S2-2).

Remote control dummy (7) in the manner of a model remote control with

 at least two operating elements (10) which are designed as control sticks and are adjustable in accordance with the adjustment positions of the control sticks of a model remote control between a plurality of adjusting positions within an adjustment range (V),

 - At least one actuator (1 1) per control element (10), wherein the actuator (1 1) is formed and arranged to adjust the respective operating element (10) between the adjustment positions, and

 - At least one control unit (13) which is designed and arranged to control the at least one actuator (1 1) per control element (10) and by means of at least one actuator (1 1) the adjustment position of the respective control element (10) with respect to a target -Verstellposition to regulate, wherein the adjustment range (V) defines limits of the possible target adjustment positions.

9. System (3) for the haptic switching of remote control movements, with

 - At least one haptic control device (31) comprising

 - A remote control (1) according to one of the preceding claims, and / or

 - A remote control dummy (7) according to claim 8, and

 - At least one instance (32) for providing second control signals (S2, S2- 1, S2-2), from which a desired adjustment position of the at least one

Operating element (10) of the at least one haptic control device (31) is derivable, wherein the second control signals (S2, S2-1, S2-2) of the of the at least one haptic control device (31) can be transmitted.

10. System (3) according to claim 9, characterized in that the at least one entity (32) comprises a remote control (1) according to claim 7.

11. System (3) according to claim 9 or 10, characterized in that the at least one entity (32) comprises a computer (320) and / or a server (321), in particular with one on the computer (320) and / or the Server (321) installed model simulation software.

12. System (3) according to at least one of claims 9 to 1 1, characterized in that the at least one haptic control device (31) comprises a remote control (1) for a real movable object (5) according to one of claims 1 to 7, wherein the object (5) comprises a telemetry unit (51) for acquiring measurement data, and in that the entity (32) comprises the telemetry unit (51), wherein the second control signals (S2, S2-1, S2-2) can be derived from the measurement data are.

13. A method for the haptic switching of remote control movements, which using a system (3) according to one of claims 9 to 12, the following

Steps includes:

 Providing the second control signals (S2, S2-1, S2-2) by the at least one entity (32), the second control signals (S2, S2-1, S2-2) having a respective desired adjustment position of the at least one operating element ( 10) of the at least one haptic control device (31) relate;

 - transmitting the second control signals (S2, S2-1, S2-2) from the entity (32) to the at least one haptic operator device (31); and

 - Regulation of the adjustment of the at least one operating element (10) of the at least one haptic control device (31) with respect to the respective desired adjustment position by means of the at least one control unit (13) and the at least one actuator (1 1).

14. The method according to claim 13, characterized in that the at least one operating element (10) of the at least one actuator (1 1) for adjusting the adjustment position with an even greater force (F) and / or with a larger torque (M) is acted upon, the further the adjustment position of the at least one operating element (10) deviates from the respective desired adjustment position.

15. The method according to claim 14, characterized in that at a deviation between the adjustment position of the at least one operating element (10) and the respective desired adjustment position, the at least one operating element (10) by the at least one actuator with a greater force (F) and / or with an even greater torque (M) is applied, the greater a coupling strength for the at least one operating element (10) is selected, wherein the coupling strength at the at least one haptic control device (31) and / or at the at least one instance ( 32) is set.

16. The method according to at least one of claims 13-15, characterized in that at least two remote controls (1 -1, 1 -2) are used according to claim 7, wherein

 - On the one hand, a first remote control (1 -1) as a first instance (32-1) for a second remote control (1-2) as a first haptic control unit (31 -1) is used, wherein the desired adjustment position of the at least one operating element (10) corresponds to the second remote control of an adjustment position of a corresponding operating element (10) of the first remote control (1 -1), and

 on the other hand, the second remote control (1 -2) is used as a second instance (32-2) for the first remote control (1 -1) as a second haptic control unit (31 -2), wherein the desired adjustment position of the at least one operating element (10) of the first remote control (1 -1) corresponds to an adjustment position of a corresponding operating element (10) of the second remote control (1 -1).