MEASURING SYSTEM FOR MEASURING THE HAND/EYE REACTION ABILITY

Abstract

The invention relates to a measuring system for reproducibly measuring reaction time curves in the case of a complex neurocognitive task. For this purpose, human influences are largely prevented when carrying out the experiment. As a result of external data processing, the measuring system is able to form an independently growing and anonymous data basis which increases in accuracy due to the continuously increasing amount of data therein. This also allows statements to be made about potentially dangerous changes in reaction times up to the indication and/or identification of neurodegenerative diseases.

Claims

1. A measuring system for measuring hand-eye reaction, comprising a measuring body, at least one force source, at least one holding device, at least one triggering unit, at least one first sensor unit, wherein the first sensor unit is designed to measure acceleration, at least one second sensor unit, at least one interface for data transmission, wherein said interface is designed to transmit computer-readable signals, and at least one data processing unit.

2. The measuring system according to claim 1, wherein the measuring body is a rod and has a length in the range from 10 cm to 120 cm and/or a diameter in the range from 4 mm to 55 mm and/or a mass in the range from 50 g to 1500 g.

3. The measuring system according to claim 1, wherein the triggering unit is a magnetic triggering unit, an electronic triggering unit, an electromagnetic triggering unit or a mechanical triggering unit.

4. The measuring system according to claim 1, wherein the at least second sensor is selected from a distance sensor, an acceleration sensor and/or a force sensor suitable for measuring grip force.

5. The measuring system according to claim 1, wherein the at least one sensor unit and the data processing unit are telemetrically connected to one another.

6. The measuring system according to claim 2, wherein the at least one sensor unit and the data processing unit are telemetrically connected to one another.

7. The measuring system according to claim 2, wherein the triggering unit is a magnetic triggering unit, an electronic triggering unit, an electromagnetic triggering unit or a mechanical triggering unit.

8. The measuring system according to claim 4, wherein the at least second sensor is an optical distance sensor, a piezoresistive pressure sensor, a piezoelectric pressure sensor, or a capacitive pressure sensor.

9. The measuring system according to claim 7, wherein the at least second sensor is selected from a distance sensor, an acceleration sensor and/or a force sensor suitable for measuring grip force.

10. A method for quantifying reaction times comprising the steps of: a) providing a measuring system according to claim 1, b) positioning a test subject relative to the measuring system, c) starting the measurement, d) randomly triggering the force effect, e) detecting the acceleration curve over the measurement duration, f) detecting all additional sensor information, g) transferring all sensor data to the data processing unit, a. logging the determined data, b. storing the determined data, c. comparing the acquired data with the existing data set, d. analyzing the curve values, h) outputting the evaluation result.

11. The method according to claim 10, wherein method steps a) to c) and/or method steps d) to f) and/or method steps g) b. to g) d. can be in any order in each case.

12. The method according to claim 10, for measuring reaction time curves in the field of movement, movement analysis, physical training, or medicine.

13. The method according to claim 12, for measuring reaction time curves in the field of physical training, wherein the physical training is in particular in the field of rehabilitation.

14. The method according to claim 12, for measuring reaction time curves in the field of medicine, in the case of neurodegenerative disease.

15. The method according to claim 14, wherein the neurodegenerative disease is a synucleinopathy or tauopathy.

16. The method according to claim 14, wherein the neurodegenerative disease is selected from Parkinson's disease, multiple system atrophies, Lewy body dementia, or Alzheimer's disease.

17. The measuring system according to claim 9, wherein the at least second sensor is an optical distance sensor, a piezoresistive pressure sensor, a piezoelectric pressure sensor, or a capacitive pressure sensor.

18. The measuring system according to claim 3, wherein the at least one sensor unit and the data processing unit are telemetrically connected to one another.

19. The measuring system according to claim 4, wherein the at least one sensor unit and the data processing unit are telemetrically connected to one another.

20. The measuring system according to claim 19, wherein: the measuring body is a rod and has a length in the range from 10 cm to 120 cm and/or a diameter in the range from 4 mm to 55 mm and/or a mass in the range from 50 g to 1500 g; and the triggering unit is a magnetic triggering unit, an electronic triggering unit, an electromagnetic triggering unit or a mechanical triggering unit.

Description

[0080] The invention will be explained in greater detail below with reference to some embodiments and accompanying drawings. The embodiments are intended to describe the invention without limiting it.

[0081] FIG. 1 is a perspective sketch of an embodiment. The stand having the holding device, the measuring system designed as a rod, and the guide cables which secure the measuring system against tipping over in an uncontrolled manner can be seen.

[0082] FIG. 2 is a sketch with possible dimensions of an embodiment, in which the measuring system rests in a height-adjustable stand. The minimum height of the height-adjustable stand is given here—the stand is in the retracted state.

[0083] FIG. 3 is a sketch with possible dimensions of an embodiment, in which the measuring system rests in a height-adjustable stand. The maximum height of the height-adjustable stand is given here—the stand is in the extended state.

[0084] FIG. 4 shows the measurement of the acceleration curves of three orthogonal acceleration sensors over a common time axis. The diagram at the top of the page shows the acceleration along the x-axis. The x-axis in this case assumes the test subject's direction of view, which extends rigidly straight ahead.

[0085] The middle diagram shows the acceleration time curve along the y-axis. The y-axis in this case follows the horizon line in a parallel or anti-parallel manner.

[0086] The diagram at the bottom of the page shows the acceleration along the z-axis. The z-axis, which is perpendicular to the x-axis and the y-axis, points along the radius of the earth.

[0087] In particular, in the diagram of the z-axis, a negative curve of the acceleration can be seen at the time 0.95 s. This is the moment at which the triggering unit randomly releases the rod. This is followed by a phase of constant acceleration, which lasts from approx. 1 s to 1.15 s. Here, the rod is in free fall. Subsequently, a steep positive deflection of the acceleration can be seen at the time 1.25 s. Here, the test subject catches the rod and holds the rod for the subsequent period of time.

[0088] From the data of the x-axis and y-axis, a trembling movement of the rod can be measured immediately after it has been caught.

[0089] FIG. 5, in addition to the measurement of the acceleration curve, shows the measurement of the distance and the grip force. The time base in this case corresponds to the same as in FIG. 4. In the diagram at the top of the page, the optically measured curve of the distance from the top of the rod, the top cap, to the holding device is plotted over time. In the middle diagram, the computed value of the distance is plotted, which results from the mechanical laws of acceleration. In this case, the constant increase in distance after the rod has been caught at the time 1.25 s is not the rod and the holding device physically approaching one another, but an artifact of the data analysis.

[0090] In the diagram at the bottom of the page, the measured grip force is plotted over time. The spontaneous and strong release of the sensor ensures a brief over-response at the time 1.25 s. After the rod has been securely caught and the information has been processed by the brain, a decrease in the grip force—the state of relaxation—occurs.

[0091] FIG. 6 schematically shows a flow diagram of the method and the measuring operation. This begins with the entry of personal data, such as age, gender, physical condition or previous illnesses. The test is started and completed and the combination of personal data and measurement data is sent to the data processing unit (cloud solution). There, the data is anonymized and compared with existing data sets in the normative database. The finished evaluated result is sent to a terminal. The user can decide whether the result of the analysis, which is available as a log, should be printed out. The resulting data set is entered into the normative database for further use after the procedure has been completed.

[0092] In one embodiment, the measuring system for measuring hand-eye reaction ability comprises the components: rod, height-adjustable stand, charging platform and software.

[0093] The rod is divided into the components “top cap” and “body”.

[0094] The body of the drop rod, the “body”, has a round cross section. The rod is made of nylon by means of 3D printing, as nylon is transparent to radio waves and does not interfere with the communication units, and has the following external dimensions:

[0095] diameter: 30 mm

[0096] length rod: 767.1 mm

[0097] total mass of the drop rod: 405 g

[0098] Two force sensors are mounted on and mechanically connected to the outer surface of the rod. These force sensors are designed as long strips having a length of 610 mm. This results in the length of the force-sensitive surface: [0099] length of the measuring range of the force sensor: 610 mm

[0100] The body houses a mother board for the control tasks in the interior of the rod, a power supply, a WiFi communication unit, and the interface for sensors and the processor CPU with firmware.

[0101] The power supply of the rod, in order to enable data acquisition, storage and transmission independently of the external energy source of the charging platform, is designed in the form of a Li-ion battery.

[0102] The upper end cap of the rod, the top cap, is made of the same material as the rod. The top cap and has the following external dimensions: [0103] length: 108 mm, [0104] width: 118 mm, [0105] height: 13 mm.

[0106] Three spring contacts are installed on the upper surface of the top cap as an interface for the charging function using the charging platform. In addition to the acceleration sensors, an optical distance sensor is also integrated into the top cap.

[0107] The acceleration sensors are arranged to measure the three orthogonal spatial directions. The acceleration sensors primarily determine the exact catch time. The distance between the upper edge of the rod and the charging platform is measured by means of the optical distance sensor. There is no need to specify an exact zero line, defined by the lower edge of the hand at the start position.

[0108] The optical distance sensor system measures the fall distance between the charging platform and the top cap, and the acceleration sensors record the catch time, among other things. There is also a unit in the top cap for opening the holding device in order to trigger the free fall.

[0109] The measuring system is integrated in the height-adjustable stand and thus allows a standardized measurement of patients with a height of 1.50 m to 1.93 m while standing and sitting. The measurement while sitting is intended for people whose body size is outside the specified limits and/or for people for whom measurement while standing is not possible because they are dependent on a wheelchair, for example. The individual test position is continuously adjusted, taking into account the height of the elbow.

[0110] In addition, a damping layer made of pur-ester acoustic foam on the base of the measuring instrument cushions the impact of the rod.

[0111] The charging platform provides the energy for the sensor units of the drop rod. For this purpose, three metallic copper contact surfaces are attached to the charging platform at the mechanical interface between the rod and the charging platform. If the rod is in mechanical contact with the charging platform, the rod is adjusted mechanically in such a way that the contact surfaces come into contact with the spring contacts of the top cap and electrical energy can be transmitted. In this way, the Li-Ion battery in the rod is charged. In order to orient the rod as intended in relation to the charging platform and to secure the drop rod against tipping over in an uncontrolled manner after falling to the ground, two guide wires are attached to the charging platform that extend through the rod and are attached to the catching device of the rod. In order to be able to provide the electrical energy, the charging platform has an interface for a power adapter for supplying power. A permanent magnet and an electromagnet are built into the charging platform to hold the rod on the charging platform. This electromagnet can be switched or controlled by a WiFi-based communication element. In this way, the holding state can be changed. This is implemented on the software side by a random generator. The random dropping of the rod is triggered within 6 s after receiving an orientation signal. [0112] Length (including charging platform) 795.3 mm

[0113] The software also allows data collection and data processing and accesses a normative database which is made available via a cloud.

[0114] The software can be operated by any WLAN-capable terminal. The user interface has a plurality of layers. These layers are [0115] the input page “Input-Page”, [0116] the test interface “Testing”, [0117] the output page “Output-Page” and [0118] the report page “Report-Page”.

[0119] In an exemplary test procedure, the relevant personal reference variables, such as age, gender, training status or previous illnesses, are entered at the “input page” layer.

[0120] The start of the test and/or trials are then initiated via the “Testing” layer. Test parameters, for example the sensitivity of the sensor units, can also be set and changed. In addition, in particular when using a controllable force source which is independent of the earth's gravitational field, the acceleration to be used can be set and/or adapted.

[0121] The results of the measurements are displayed and output visually on the “output page” layer. The data are in this case presented as absolute values and are interpreted on the basis of the comparison with the normative database and the age-specific and disease-specific limit values.

[0122] Finally, a “report page” is generated in the form of a PDF file, which clearly shows all results—including an interpretation and brief description. Every measurement is stored in the cloud. A data protection-compliant comparison of a plurality of measurements of a single person is also provided.

LIST OF REFERENCE SIGNS

[0123] 1 Top cap and charging platform [0124] 2 Rod [0125] 3 Height adjustable stand [0126] 4 Guide wires [0127] 5 Catching device comprising a tensioning mechanism for the guide wires and a damping layer [0128] 6 Foot stand [0129] 7 Power cord [0130] 8 Lever for continuous height adjustment [0131] 9 Power adapter