The invention relates to a driving simulator which is a device for the simulation of a car ride on a plane, multicurved road laterally limited by an enclosure using a monitor for the picture of the road perspectively observed by the driver, a program for the generation of the road picture, and control devices such as accelerator pedal, brake pedal, clutch pedal, and steering wheel, all of which influence the road picture, and using sound generating devices.

For introduction, it may first be explained which processes take place during a real car ride.

The picture seen by the driver through the windshield of his car shows the car front, the road, possibly other road users, the horizon, the sky, possibly surrounding objects, and so on. The road being straight, the border lines of the road are straight lines, meeting in one point jointly with the horizon line. Thus, in the plane of the picture, the horizontal distances of the two border lines increase linearly from top to bottom. At curves, this linearity is an approximation. When the direction of the car changes relative to the direction of the road, the horizontal distances also change.

A horizontal shifting of the picture corresponds to a turn of the car relative to the direction of the road, and a turn of the picture around the horizon intersection point of the road corresponds to a parallel shifting of the car relative to the middle of the road.

In order to keep the car in the middle of the road, the curvature of the car track, given by the angle of the steering wheel, has to be kept equal to the curvature of the road. Inspite of a correct steering wheel angle, the car may encounter a track deviation if the speed is so high with the given road curvature that the permissible centrifugal acceleration is exceeded and the car is drifting. This drifting is compensated with acceleration of the car in the curve.

The speed of the car depends on engaging the associated control devices and the characteristic values of the car such as air resistance, inertia, engine power, and friction etc. The deceleration, when braking, is approximately proportional to the pressure on the brake pedal up to a definite threshold. Beyond this threshold, the wheels lock-up and a deceleration results which is smaller than the maximum deceleration with rolling wheels, and is not to be influenced by further increase of the pressure on the brake pedal. Only if the pressure falls below the critical minimum pressure, the locking is released.

The most relevant noises heard by the driver during the ride are the engine noise depending on rotation and the noise of the sliding tires when drifting in curves as well as the noise when the car is braked down with full pressure.

When designing a driving simulator, the task arises to represent part of these criteria or all of them. Furthermore, a simulator may comprise phenomena which are unknown in reality, e.g. instances causing an artificial reaction of the simulator on faulty operation by the driver which would cause an accident in reality.

One driving simulator of the mentioned kind was built already. It uses a computer program by which the movement of the road borders is computed step by step digitally dependent upon the steering wheel movement and this is displayed on a screen.

However, multi-purpose digital computers with hardware and storage required by such a simulation are very expensive and are out of the question for a wide-spread use of driving simulators.

Also a general proposal is made for the layout of a driving simulator pointing out the idea to generate voltages by an analog device, according to the equations of a simplified environmental picture and to compare these voltages to saw tooth voltages synchronous to the picture and line pulses of a monitor.

However, this proposal lacks ideas for the realization thereof in actuality to a great extent; fundamental considerations are missing, and if one would pursue the indicated methods, the simulator would become a very expensive analog computer.

Therefore, the objects of the invention are as follows:

(a) to point out new principles for a driving simulation which can easily be realized technically, which are economical and nevertheless effective, and which avoid the defects of known principles,

(b) to simulate physical phenomena of a real car ride, which have not been simulated before or which have not been simulated in connection with the subject of the invention,

(c) to disclose circuits integrating well known parts or functional units by which all proposals of the invention can be realized easily and economically.

For completion, it may be mentioned that driving simulators are known which give the driver the impression of an acceleration by mechanically moving the seat. Such an effect is possible by processing the signals generated in the simulation device described below.

The individual devices comprised by the simulator according to the invention are arranged as follows:

A--devices for the generation of the road picture,

B--devices for the generation of curves,

C--devices for the alteration of the road picture with track deviations of the simulated car,

D--devices for the influence on the speed,

E--devices for the generation of noises,

F--devices for the reaction of the simulator on faulty operation of the driver,

G--devices for the termination of the driving distance and for the measuring of the driving time.

According to another idea of the invention additional devices are provided which simulate obstacles arranged somewhere in the middle of the road, in front of which the driver has to brake down. They are to be found in the arrangement under:

H--devices for obstructing the ride.

To resolve the given object, an electronic circuit is described below as a signal flow circuit with reference to the functional units and signals which are used in the figures. Thus, the description explains not only the ideas of the invention but also the functional relation between the signals and the units demonstrated on the pictures.

To (A) For the generation of the road picture, the invention provides that the enclosures are represented as sequences of equidistant rectangularly shaped border posts standing vertical and lateral. The left posts are standing exactly opposite to the right posts, thus represented by pairs of rectangular light spots 3 located horizontally side by side, depicted on the screen of a monitor 1. The distance between the two light spots of one pair increases independent of curves and of possible turns of the car linearly with the light spot distance from the horizon 4, simplifying the reality. Furthermore, a representation is chosen to increase the vertical distances of the light spot pairs in a non-linear way from top to bottom according to the perspective and to proportionally increase the size of the light spots laterally as well as longitudinally with their distance from the horizon. The front part of the car is represented as a horizontal rectangular light spot 5 at the lower part of the screen and in the middle of the screen. A photo of a car front may be covered over this light spot. The sky is represented by brightening the upper part of the screen 2.

To (B) For the generation of curves the invention provides that several types of curves and of both turn directions are generated, each of which is produced by one curve function generator 6. Hereby, the curve functions are derived from the shape of the curves and the perspective of a ride in the middle of the road. According to the invention, the light spots are horizontally shiftable with a speed being proportional to the speed of the car, whereby the distances of the two light spots of one pair are not additionally influenced. The shifting of the light spot pairs is achieved by individually shifting via a control voltage U_KL every light spot pair horizontally in addition to the normal displacement, according to a specific function. Several standard curves of different shapes and both directions are provided, each of which is generated by a curve function generator 6. According to the invention, these curve function generators are actuated by a curve program generator 7 via curve triggering signals S_KT in a way that a non-regular sequence of right and left curves and unequally long straight road sections is produced.

To (C) For alteration of the road picture with track deviations, two steps are provided. For the representation of a car turn relative to the direction of the road, all light spots shall be horizontally shiftable. For the representation of a parallel track displacement relative to the middle of the road, the light spot lines shall be turnable around a horizon intersection point. The curvature of the car track, given by the angle of the steering wheel, has to be kept equal to the curvature of the road. Therefore the invention provides the following

that a signal voltage U_K is supplied by the curve function generators which is proportional to the respective road curvature,

that an angle signal W_L is supplied by the steering wheel 8 of the simulator,

that the two signals are compared with each other in a horizontal shifting device 9, and

that the device 9 supplies a voltage U_H for the horizontal shifting of the light spots and a voltage U_S for the alteration of the gradient of the light spot lines, i.e. for turning the picture when the two curvatures are unequal.

For the simulation of drifting the invention provides the following:

that the centrifugal acceleration b_F is measured as the product of speed V times steering wheel angle W_L and compared with an adjustable threshold, and

that the track of the car deviates from the line aimed at by the steering wheel if the threshold is surpassed. According to the invention this deviation shall be achieved by influencing the control voltage U_H or by limiting the voltage which is supplied by the steering wheel.

For the representation of the influence of the acceleration on the drifting, the invention provides that the threshold of the centrifugal acceleration is made dependent upon the measured size b of the acceleration.

To (D) Extending and improving known proposals, the invention provides a simulation circuit supplying not only the speed signal but also the engine rotation signal when the clutch is gripping or not gripping.

To (E) To emphasize the impression of a real car ride and to supply to the driver additional information about the dynamic situation of the simulated car during a fast ride, the invention provides that the most relevant noises are simulated and generated by oscillators, namely, the engine noise relative to rotation and the noise of drifting tires.

To (F) Should the driver fail to properly handle the simulator by awkwardly steering or driving too fast into the curves so that the light spot for the front part of the car touches one of the light spots for the road borders, the invention provides that an error measuring signal S_FeM is generated. This signal may actuate various processes, e.g. that an error noise is initiated so that the speed is reduced, and that the light spot lines are reset in the middle of the screen. For this purpose the invention provides a monostable multivibrator 21 via which the error measuring signal S_FeM is processed into an error triggering signal S_Fe of definite duration during which the above mentioned processes occur. Furthermore, an error counter may be provided which supplies a stop signal S_AF which ends the program after a set total of errors is achieved.

To (G) To be able to evaluate the skill of the driver, a distance program generator 23 is provided which is to be started by a start signal S_E via a push button or a coin test or acceptor means 24 which first resets the curve program in its initial state and which supplies a stop signal S_AS after a certain distance is achieved which is defined by a certain number of light spot sequence periods; also provided is a clock 25 for measuring the driving time, which is started by the start signal S_E and stopped by the stop signal S_AS. Furthermore, the invention provides that a curve trigger blocking signal S_KTS is supplied by the distance program generator. Accordingly, all curves are suppressed e.g. at the end of the distance for representation of a home stretch. The invention provides that the distance is not totally passed with slow riding, but that a stop signal S_AU is supplied by the clock after a definite time period is run out, which in fact ends the ride. After the end of the ride, it is provided that the speed is reduced to zero or to a minimum value by the stop signal S_AS, and the light spot lines are reset to the middle of the screen. Resetting of the clock to zero is achieved by the start signal S_E or the stop signal S_AF (FIG. 1).

To (A) The device A for the generation of the road picture described above for introduction is specifically characterized such:

that a video signal generator 30 is provided for the representation of the sky 2, by which a video signal S_Hi is generated,

that a video signal generator 29 is provided for the representation of the car front, by which a video signal S_Wa is generated,

that one video signal generator 28 is provided for the representation of two road border posts 3, by which a video signal S_L is generated, several video signal generators 28 being provided,

that all video signals are added in a known way in an OR-gate and supplied to a monitor 1,

that the video signal generators 28 are supplied by a control voltage U_H for the common horizontal shifting of the light spots,

that the individual video signal generators 28 are supplied by the periodical voltage U_A for the vertical deflection and the longitudinal and lateral size alteration of the light spots, by the voltage U_Al for the horizontal deflection of the left light spot, by the voltage U_Ar for the horizontal deflection of the right light spot, by the digital signal S_R for the darkening of the return movement of the light spot pair, and by a number of voltages U_KL for the horizontal shifting of the light spot pair at curves, and

that a deflection voltage generator 31 is provided to which the speed signal V and the control voltage U_S for the alteration of the gradient of the light spot lines are supplied.

For measuring of errors, AND-gates 32 are provided to each of which a video signal S_L and a video signal S_Wa are supplied, and the outputs of which are supplied to an OR-gate 27 which supplies an error measuring signal S_FeM if one of the video signals S_L occurs simultaneously with the video signal S_Wa (FIG. 2).

Devices for the generation and alteration of a video signal are known. They comprise a horizontal synchronous pulse generator 35 and a vertical synchronous pulse generator 37, the output signals S_HS and S_VS of which are delayed in delaying circuits 34 and extended in extension circuits 36 and combined in an AND-gate 32 to the video signal S_L. The inventive video signal generator 28 differs from the known video signal generators by the specific performance as a twin spot generator and the specific control voltage supply. It is characterized such,

that the horizontal pulse voltages S_Hl und S_Hr for the left and the right light spot are generated by one pulse generator 35 and combined in an OR-gate 27 to the horizontal twin pulse voltage S_H,

that a signal S_R inverted in an inverter 33 for the darkening of the back movement is additionally supplied to the AND-gate 32,

that the extension of the two horizontal pulses and the extension and the delay of the vertical pulse are controlled by the common deflection voltage U_A,

that the delay of the right horizontal pulse is controlled by the sum of the signal voltages U_H, U_KL, and U_Ar, and

that the delay of the left horizontal pulse is controlled by the sum of the signal voltages U_H, U_KL, and the voltage U_Al inverted in a polarity inverter 38 (FIG. 3).

The device 31 for the generation of the deflection voltages for the video signal generators described above for introduction meets the object to move the light spots in such a way across the screen that the observer gets the impression of a third dimension and of moving right into the picture. According to the invention the deflection is linear within one road section, i.e. while passing between two light spot pairs. The representation of the border posts near the horizon is waived. The consequence is a limited view distance and a limited number of light spot pairs appearing simultaneously in the picture. Every light spot pair runs through the picture from top to bottom according to a time function being composed of linear sections down to the bottom of the picture and returns darkened during one section into the upper initial position. This process repeats periodically. Thus, always one of the provided light spot pairs is darkened and returning.

The device of the deflection voltage generator is specifically characterized thus,

that a saw tooth generator 39 is provided and the frequency thereof is controlled by the speed signal V,

that a triggering device 40 is provided by which the saw tooth voltage U_Sae is converted into a digital periodical signal S_PA by which the distance of the light spot pairs is defined,

that a light spot sequence counter 41 is provided which supplies a periodical signal S_PF after all light spot pairs have run through the picture, the intermediate outputs of counter 41 being supplied to a road section generator 42 supplying current switching signals S_S by which discrete road sections are defined,

that an electronic switch 43 for each section is provided by which the pertaining speed signal V is supplied to a polarity inverter 38 during the section concerned,

that the switched speed signals, inverted and not inverted, are fed to a valuation matrice 44 via which, for each light spot pair, an integrator charged and discharged in a way that is generates a periodical deflection voltage according to the driving simulation, being nonlinear and composed of linear sections,

that a further matrice is provided, equalling said matrice 44, by which in a similar way a deflection voltage U_Ar is generated, the size of which is however influenced by the control voltage U_S in addition to the speed signal,

that a further matrice is provided, equalling said matrice 44, by which in a similar way the deflection voltage U_Al is generated, the size of which is influenced subtractively by the control voltage U_S in addition to the speed signal, and

that the switching signals S_S of the individual sections are supplied to the video signal generators 28 in a way that the last section of its periodical sequence is darkened (FIG. 4).

To (B) The device 6 for the generation of curve functions described above for introductory purposes meets the object to deflect the individual light spot pairs in a way that the observer has the impression of the curve being traversed by driving the car in the middle of the road. According to the invention, this deflection occurs linearly during one section of the curve, i.e. during one section of the road. The length of the total curve function is composed of the first section simulating the straight approach of the car to the beginning of the curve and the second section simulating the driving in the curve. Thus, the total length of the curve function is longer than the view distance and may be a multiple of the view distance. That means, it is composed of at least two partial functions each of which beginning at zero, ascending to a certain value during the darkened section, and leading to zero again according to an appropriate function. Specific curves are simulated which are composed of three sections: a clotoide, a circle arc, and a secnd clotoide. Thus, the curvature first ascends linearly, then stays constant, and then descends linearly to zero. According to the invention these three sections are integer multiples of the road sections.

According to the invention, the curve function generator 6 is characterized thus,

that a curve section counter 46 is provided which is supplied by the periodical light spot distance signal S_PA and actuated by a curve triggering signal S_KT in the case of no curve trigger blocking signal S_KTS being supplied, and the intermediate outputs of which are supplied to a curve section generator 47 which supplies one sequence of switching signals S_S after each actuation, by which curve sections are determined,

that an electronical switch 43 is provided for every section, by which the speed signal V is supplied to a polarity inverter 38 during the concerned section, and

that the switched speed signals, inverted and not inverted, are fed to an evaluation matrice 48 via which an integrator 45 for every light spot pair is charged and discharged in a way that it generates a control voltage U_KL according to the shape of the curve, being non-linear and composed of linear sections for the horizontal shifting of the light spot pair, and via which an additional integrator 45 is charged and discharged in a way that generates a signal voltage U_K proportional to the curvature of the road (FIG. 5).

The device 7 for the generation of a curve sequence program generator described above for introductory purposes is specifically characterized thus,

that one or several curve sequence counters 49 for each type of curve are provided, which are supplied by the periodical light spot sequence signal S_PF, by which different integers are periodically counted defining the distance of the curves, which count only when they are set in operation by the inverted stop signal S_AS, and the intermediate output signals of which are supplied to curve sequence section generators 50 which supply curve sequence section signals S_KF lasting a period of one light spot sequence,

that all curve sequence section signals of one type of curve are added in an OR-gate 27, and

that the output of the OR-gate, combined with a curve synchronous signal S_KS being supplied by the deflection voltage generator 31 is supplied to an AND-gate 32, the output of which is the curve triggering signal S_KT (FIG. 6).

To (C) The device for the horizontal shifting of the light spots described above for introduction meets the object to alter the road picture in the event of turning and parallel shifting of the car. If the curvature of the car track being controlled by the steering wheel does not agree with the curvature of the road being supplied by the curve function generator, a picture shifting shall be achieved first, which is dependent on the deviation according to an integral time function and which is a transformation of the turning of the car relative to the axis of the road. Depending on the ratio of the car length to the road width, also a picture turning shall be achieved simultaneously. According to the invention, the ratio between the turning and the shifting of the picture shall be adjustable. An additional adjustable turning of the picture, which is a transformation of the parallel car shifting, shall be dependent on the picture shifting according to a second integral time function. In order to represent the drifting of the car, the curvature of the car track shall be limited at high centrifugal acceleration. To display the drifted also optically, the invention provides furthermore that an alternating voltage of appropriate amplitude and slow frequency is superimposed as to the direct voltage limiting the centrifugal acceleration.

The device for the horizontal shifting of the light spots is specifically characterized thus,

that two multiplying devices 51 are provided by which the steering wheel angle W_L and the voltage U_K proportional to the curvature of the road are multiplied with the speed signal V,

that a limiting device 53 is provided by which the product W_L · V is limited for both polarities,

that the output of the limiting device and the product U_k · V are subtracted in a subtracting device 20,

that the difference is supplied to an integrator 61,

that the output of the integrator first delivers the control voltage U_H for the common light spot shifting and secondary is supplied to a second multiplying device 51,

that the output of this multiplying device is supplied to an integrator 62,

that the output of this integrator delivers the control voltage U_S for the alteration of the gradient of the light spot lines,

that evaluation devices 52 and adding devices 20 are provided by which said signals are added and balanced,

that the integrators are discharged by a digital signal which is the output of an OR-gate 27 having as inputs the stop signal S_AS and the error signal S_Fe,

that the limit of the limiting device 53 is controlled by an adjustable signal b_F Grenz to which moreover the evaluated signal b of the acceleration and an alternating voltage is added,

that the product b_F of the steering wheel angle W_L and the speed signal V is supplied via a rectifier 55 to a threshold device 54, the threshold of which is supplied by the sum of the centrifugal acceleration limit b_F Grenz and the evaluated acceleration signal b, and

that the excessive centrifugal acceleration b_F exz is used as an output signal (FIG. 7).

The device for the horizontal shifting described above is not the only possible one to be considered. The advantage is just that the multiplication of the steering wheel angle by the speed signal can simply be achieved by supplying the speed signal to an adjustable resistor controlled by the steering wheel. Using this method an electronic or electrical multiplying device is not necessary.

Another simplification is provided whereby the multiplying device 51 multiplying the speed signal V and the signal U_K for the curvature of the road is waived by feeding into the integrator not the speed signal V but the square V². Using this method, the changes in speed occuring during a curve have to be taken into account. A device meeting this object is characterized thus,

that a squaring circuit 68 is provided by which the speed signal V is squared,

that for each type of curve, a curve section generator 47 is provided supplying the two parts of the curve where the curvature is changing,

that an electronic switch 43 is provided for each part of the curve, via which the squared speed signal is supplied to an adding device 20 during the period, involved or concerned therewith

that the signal V² is supplied directly to the adding devices during the first period and via a polarity inverter 38 during the second period,

that furthermore, the time gradient of the speed signal supplied by differential devices 69 is supplied to the adding devices,

that the outputs of the adding devices are fed to integrators 45, and

that the outputs of the integrators are added to form signal V · U_K (FIG. 11).

A specific simplification of the circuit can be achieved according to the invention by totally neglecting the turning of the picture. This simplification is characterized by waiving the devices for the generation and the processing of the control voltage U_S and the deflection voltages U_Ar and U_Al and by using instead the deflection voltage U_A also for the horizontal shifting of the light spots.

To (D) The device 10 for the computation of the speed of the simulated car is partly known. It is designed in a way,

that a first grade delay circuit 63 is provided having the steady state amplifying factor defined by the air resistance of the car, the time constant of which is defined by the inertia of the car, and the output of which delivers the speed signal V,

that an evaluation circuit 65 is provided by which input voltage thereof is valued according to the gear ratios and the gear defined by signal S_G and the output U_An of which is supplied to the input of the delay circuit 63,

that a voltage U_Gas is supplied from the accelerator pedal to the input of the evaluation circuit 65 via a switch 56 to be opened by the clutch signal S_Ku, and

that furthermore a voltage U_Br is supplied by the brake pedal and a constant voltage U_Rei represents the frictional forces supplied with negative polarity to the input of the delay circuit 63.

The additional devices acording to the invention are characterized thus,

that a constant voltage U_AS for the reduction of the speed at the end of the program and in the event of errors is supplied furthermore to the input of the delay circuit 63 with negative polarity via a switch 43,

that the switch 43 is closed by the output of an OR-gate, the inputs of which are supplied by the signals S_AS and S_Fe,

that a display 57 for the speed is provided,

that another delay circuit 64 of first grade is provided; the steady state amplification factor thereof is defined by the damping of the piston stroke movement, the time constant of which is defined by the rotating inertia of the engine, and the output of which is the rotation signal n,

that the input of this delay circuit can be switched over by the clutch signal S_Ku,

that a control amplifier 67 is provided subtracting at its input the rotation signal n as actual value and the speed signal reduced by a second evaluation circuit 65 as reference value,

that the output of the control amplifier is connected to the input of the delay circuit 64 with a gripping or engagement or a clutch and that the torque m is connected to the input of the delay circuit with an opening or disengagement of a clutch,

that several threshold devices 54 are provided with the inputs to which the rotation signal n is supplied and the thresholds of which are adjusted by constant voltages U_Kn,

that the excessive rotation signals supplied by the outputs of the threshold devices are subtracted via evaluation devices 52 from the voltage U_Gas supplied by the acceleration pedal, the subtraction being required to reduce the engine torque with increasing rotation,

than an interlocking circuit 66 is provided which transmits a signal S_Sch supplied by the gear shift 14 only when a signal S_Ku is given by the clutch pedal and the output of circuit 66 supplies the signal S_G for the determination of the effective gear,

that a differential circuit 58 is provided converting the speed signal into an acceleration signal b which is supplied to a polarity inverter 38 that supplies the deceleration signal v,

that a "Schmitt"-trigger 59 with hysteresis is provided relative to which the deceleration signal v is supplied and the thresholds of which are the constant voltages v_An and v_Ab,

that a threshold device 54 is provided to which also the deceleration signal v is supplied, the threshold of which is the constant voltage V_Ru and the output of which is supplied to an electronic switch 43 actuated by the output signal S_Ru of the "Schmitt"-trigger 59, and

that the switched excessive deceleration signal is supplied to a control amplifier 60, the output U_Ru of which is added to the input of the delay circuit 63 (FIG. 8).

A specific simplification of the circuit for the speed computation is characterized by waiving the clutch pedal and all devices being influenced by the switching signal of the clutch pedal.

To (E) The device E for the generation of the noises is characterized thus,

that the computing device for the speed supplies the rotation signal n to an oscillator 15,

that the frequency of the oscillator is proportionally influenced by the rotation signal,

that the generated oscillation signal u_M is supplied to a sound amplifier 17 with loudspeaker 18 once directly and once via an evaluation device 16 adjusted by the position of the accelerator pedal,

that a second oscillator 19 is provided with the output signal u_D thereof composed of partial oscillations and added to the input of the sound amplifier 17 and which is adjustable in volume by the signal b_Fexz for excessive centrifugal acceleration and by the signal S_Ru for high deceleration, and

that a third oscillator 26 is provided with the output signal u_Fe thereof also added to the sound amplifier 17 and which is adjustable in volume by the error signal S_Fe (FIG. 9).

To (G) The device for the generation of the distance program is characterized thus,

that a counter 70 is provided to which the periodical light spot sequence signal S_PF is supplied and which is set into operation by the permanent-on signal S_ED, which supplies a distance end signal S_StrE after having counted a definite integer, and the intermediate outputs of which are supplied to a distance generator 71 which supplies the curve trigger blocking signal S_KTS,

that the permanent-on signal is supplied by a feed back circuit 72 which is closed by the start signal S_E and which is opened by the stop signal S_AS,

that an OR-gate 27 is provided which supplies the stop signal S_AS and to which the stop signal S_AU from the clock, the stop signal S_Af from the error counter and the inverted output of the AND-gate combining the permanent-on signal S_ED and the inverted distance end signal S_StrE are supplied (FIG. 10).

To (H) The device H for the generation of an obstacle is characterized according to the invention thus,

that an additonal video signal generator is provided by which the light spot for an obstacle is generated in the middle of one light spot pair and which is controlled by the deflection voltages of this light spot pair,

that the deflection lasts only during one period of the light spot sequence,

that the obstacle light spot is triggered with irregular distances by a separate obstacle sequence program generator functioning like a curve sequence program generator, and

that an obstacle error signal is supplied if the speed exceeds an adjustable minimum value when the obstacle light spot touches the light spot representing the car front.

All functional units of this additional device are shown in the figures already and are explained in the description. An additional figure is therefore waived.

To the figures:

The figures show the signal processing functional units as blocks with input and output signals, the topological connections between signals and blocks, and the directions of the signals. The functioning of the circuits is explained in the description of the driving simulator. The meaning of the device numbers is set forth in the table for devices; the meaning of the signal symbols is set forth in the table for signals.

FIG. 1 is a survey of the driving simulator comprising all known and new devices except those for obstructing the ride. The blocks are shown in detail in the following figures. In the example of FIG. 1 two types of curve are provided, one right curve and one left curve. Therfore, two curve function generators 6, two curved triggering signals S_KT, two signal voltages U_K proportional to the curvature of the curve, and two groups of control voltages U_KL are shown.

FIG. 2 shows the devices for the generation of the road picture which are shown in FIG. 1 as block A. In the example of FIG. 2, five light spot pairs are provided. Therefore, five video signal generators 28 and the pertaining inputs, outputs, and AND-gates are shown in addition to the video signal generators for the sky and the car.

FIG. 3 shows the device for the generation and the alteration of a video signal (video signal generator) for one light spot pair, which is shown in FIG. 2 as block 28.

FIG. 4 shows the device for the generation of the deflection voltages (deflection voltage generator), which is shown in FIG. 2 as block 31.

FIG. 5 shows the device for the generation of the curve functions (curve function generator), which is shown in FIG. 1 as block 6. In this example, 7 curve sections and 5 light spot pairs are provided. Therefore, 7 electronic switches 43 with the pertaining polarity inverters 38 and 5 integrators 45 are shown.

FIG. 6 shows the device for the generation of a curve sequence program (curve sequence program generator) which is shown in FIG. 1 as block 7. In this example, two curves, namely one right curve and one left curve and for either curve two counting sequences are provided. Therefore, two curve triggering signals S_KTr and four curve sequence counters 49 are shown together with the pertaining curve sequence section generators 50 and their output signals.

FIG. 7 shows the device for the horizontal shifting of the light spots at deviations of the track of the car, which is shown in FIG. 1 as block 9.

FIG. 8 shows the computing device for the computation of the speed, which is shown in FIG. 1 as block 10.

FIG. 9 shows the devices for the noise generation which is shown in FIG. 1 as block E.

FIG. 10 shows the device for the generation of a distance program (distance program generator), which is shown in FIG. 1 as block 23.

FIG. 11 shows a device for multiplying the speed by the curvature of the road as an alternative to the circuits shown in the FIGS. 5 and 7.

It is, of course, to be understood that the present invention is, by no means, limited to the specific showing in the drawing but also comprises any modifications within the scope of the appended claims.

SIGNALS:

b -- Signal voltage for the acceleration of the simulated car

b_F -- Signal voltage for the centrifugal acceleration

b_Fexz -- Signal voltage for the excessive centrifugal acceleration

b_FGrenz -- limit for the centrifugal acceleration

l -- subscript for left

m -- signal voltage for the torque of the simulated engine

n -- signal voltage for the rotation of the simulated engine

r -- subscript for right

S -- general: digital signal voltage

S_af -- stop signal from the error counter

S_as -- stop signal

S_au -- stop signal from the clock

S_e -- start signal

S_ed -- permanent-on signal

S_f -- video signal for the generation of all light spots

S_fe -- error triggering signal

S_feM -- error measuring signal

S_g -- signal for the gear in operation

S_h -- horizontal pulse voltage

S_hi -- video signal for the generation of the light spot for the sky

S_hs -- horizontal synchronous pulse voltage

S_kf -- curve sequence section signal

S_ks -- curve synchronous signal

S_kt -- curve triggering signal

S_kts -- curve trigger blocking signal

S_ku -- switching signal supplied by the cluch pedal

S_l -- video signal for the generation of a light spot pair

S_p -- program signal

S_pa -- periodical light spot pair distance signal

S_pf -- periodical light spot sequence signal

S_r -- darkening signal for the return movement

S_ru -- signal for sliding under deceleration

S_s -- switching signal for electronical switches

S_sch -- signal supplied by the gear shift

S_strE -- distance end signal

S_v -- vertical pulse voltage

S_vs -- vertical synchronous pulse voltage

S_wa -- video signal for the generation of the light spot for the car front

U -- general: analog signal voltage

u -- general: alternating voltage

U_a -- nonlinear periodical deflection voltage

U_an -- control voltage for wheel torque

U_as -- constant voltage for the reduction of the speed at the end of the program and at errors

U_br -- voltage supplied by the brake pedal

u_D -- sound frequency signal for the drifting noise

U_dr -- control voltage for the representation of the torque reduction dependent on the rotation

u_Fe -- sound frequency signal for the error noise

U_gas -- control voltage supplied by the accelerator pedal

U_h -- control voltage for the common horizontal light spot shifting

U_k -- signal voltage being proportional to the curvature of the road

U_kl -- control voltages for the horizontal shifting of the individual light spot pairs at curves

U_kn -- inflexion voltage of the rotation-torque characteristic

u_M -- sound frequency signal for the engine noise

U_rei -- constant voltage for the representation of the frictional forces

U_ru -- control voltage for the control of the sliding deceleration at full braking

U_s -- control voltage for the alteration of the gradient of the light spot lines

U_sa -- saw tooth voltage

V -- speed signal

v -- voltage proportional to the deceleration

v_An -- threshold for increasing voltages of the "Schmitt"-trigger

v_Ab -- threshold for decreasing voltages of the "Schmitt"-trigger

v_Ru -- deceleration at sliding

W_l -- angle of the steering wheel

X_g -- position of the accelerator pedal

DEVICES:

A -- devices for the generation of the road picture

B -- devices for the generation of curves

C -- devices for the alteration of the road picture at track deviations of the simulated car

D -- devices influencing the speed

E -- devices for the generation of noices

F -- devices for the reaction of the simulator at faulty actions of the driver

G -- devices for the generation of the distance and for measuring the driving time

H -- devices for obstructing the ride

1 -- monitor

2 -- top part of the screen for representation of the sky

3 -- light spots for the representation of embankment posts

4 -- horizon

5 -- immobile light spot for the representation of the car front

6 -- curve function generators

7 -- curve sequence program generator

8 -- steering wheel

9 -- horizontal shifting control device

10 -- computing device for speed computation

11 -- accelerator pedal

12 -- brake pedal

13 -- clutch pedal

14 -- gear shift

15 -- oscillator for the generation of the engine noise

16 -- evaluation device

17 -- sound frequency amplifier

18 -- loudspeaker or earphone

19 -- oscillator for the generation of the drifting noise

20 -- adding or subtraction device

21 -- monostable multivibrator

22 -- error counter

23 -- distance program generator

24 -- push button or coin acceptor

25 -- clock

26 -- oscillator for the generation of an error noise

27 -- OR-gate

28 -- video signal generators for light spot pairs

29 -- video signal generator for the car front

30 -- video signal generator for the sky

31 -- deflection voltage generator

32 -- AND-gate

33 -- inverter for digital signals

34 -- pulse delaying circuit

35 -- horizontal synchronous pulse generator

36 -- pulse extension circuit

37 -- vertical synchronous pulse generator

38 -- polarity inverter

39 -- saw tooth generator

40 -- triggering device

41 -- light spot sequence counter

42 -- road section generator

43 -- electronical switch

44 -- evaluation matrice for the simulation of the ride

45 -- integrators

46 -- curve section counter

47 -- curve section generator

48 -- evaluation matrice for the curve simulation

49 -- curve sequence counter

50 -- curve sequence section generator

51 -- multiplying device

52 -- evaluation device

53 -- limiting device

54 -- threshold device

55 -- rectifier

56 -- switch

57 -- measuring instrument

58 -- differentiating device

59 -- "Schmitt"-trigger

60 -- control amplifier for the control of the sliding deceleration at full braking

61 -- integrator for the determination of the track-angle depending on the steering deviation proportional to speed

62 -- integrator for the determination of the parallel track shifting dependent on the track-angle porportional to speed

63 -- first grade delay circuit according to the inertia of the car

64 -- first grade delay circuit according to the centrifugal inertia of the engine

65 -- evaluation circuit according to the ratios of three or four gears

66 -- interlocking circuit

67 -- control amplifier for the control of the rotation derived from the evaluated speed, the clutch gripping

68 -- squaring circuit

69 -- differentiating circuit

70 -- distance program counter

71 -- distance section generator

72 -- holding circuit