DE202017102858U1 - Simulation of a blind guidance system - Google Patents

Abstract

An electronic device (10) for learning a path (42) for the visually impaired, comprising a) a touch-sensitive surface (14), b) a vibration mechanism (34), c) a voltage source (18) for powering electronic components (22), d ) a processor-controlled control mechanism (28) having a memory (26) for digitally storing a path model, characterized by e) an electronic simulation mechanism (32) which, with the control mechanism, projects the path model onto the touch-sensitive surface (14) while contacting path areas the device vibrates and / or emits other detectable signals for the visually impaired.

Description

Technical area

• a) eine berührungsempfindliche Fläche,
• b) einen Vibrationsmechanismus,
• c) eine Spannungsquelle zur Spannungsversorgung von elektronischen Bauteilen,
• d) einen prozessorgesteuerten Steuerungsmechanismus mit einem Speicher zur digitalen Speicherung eines Wegmodells.

The innovation relates to an electronic device for learning a route for the visually impaired, comprising

• a) a touch-sensitive surface,
• b) a vibration mechanism,
• c) a voltage source for supplying power to electronic components,
• d) a processor-controlled control mechanism with a memory for digital storage of a path model.

description

For the visually impaired, who enter an unknown building, it is difficult to orient themselves. Many public buildings have relief tiles that show the visually impaired. Nevertheless, it proves to be problematic for the visually impaired to orient themselves in new premises. For the blind and visually impaired, participation in public life already reaches its limits when it comes to mobility.

Already everyday errands, such as the way to the butcher, the bank or a doctor's visit, regularly require their sighted fellow human beings. The so-called "blind stick" is an important aid for the visually impaired to capture the path and its surroundings. For them, the movement space is usually limited to previously rehearsed paths. For this, important waypoints are memorized so that they can be used later for orientation.

It also technical tools, such as the smartphone, used. For this purpose, for example, an individual route for the visually impaired is developed on a home computer and transferred to a smartphone. Smartphones often have a satellite-based "GPS system" that makes it easy to locate them. At certain waypoints of the transmitted route the smartphone vibrates. In this way, the visually impaired can move outside.

One problem with this system, however, is that the GPS system does not work in buildings. The GPS system does not regularly detect signals sent by satellites in buildings. Therefore, a visually impaired person can use this tool only conditionally or not at all in buildings. Another disadvantage of this system is that the visually impaired needs at least one hand for the blind stick. So it's extremely unwieldy to keep both the blind stick and the smartphone. Both hands are needed in this system for orientation, however.

State of the art

From the EP 2 133 663 B1 a device is known, with which the pedestrian navigation is supported by visually impaired and blind users. In this case, the position of the user is transmitted to a user-portable processing terminal by means of a positioning satellite system. The user position is then communicated to a guidance information processing module. At this time, guide information obtained based on the user position is sent from the guidance information processing module to the portable processing terminal which generates a response corresponding to the location of the visually impaired person.

Disadvantage of the known aids for the visually impaired is in particular that they do not necessarily work in confined spaces, since the position signal transmitted by satellites can not be processed. The learning of ways is therefore often on suitable cards for the visually impaired, which can be scanned by them.

Revelation of innovation

The task of the innovation is therefore to create a tool for the visually impaired, with which they can easily study the way of a building to later find waypoints and estimate distances.

• e) ein elektronischer Simulationsmechanismus vorgesehen ist, welcher mit dem Steuerungsmechanismus das Wegmodell auf die berührungsempfindliche Fläche projiziert, wobei bei Berührung von Wegbereichen die Vorrichtung vibriert und/oder andere für den Sehbehinderten erfassbare Signale aussendet.

According to the innovation, the object is achieved in that in a device for learning a way for the visually impaired of the type mentioned

• e) an electronic simulation mechanism is provided which, with the control mechanism, projects the path model onto the touch-sensitive surface, whereby the device vibrates and / or transmits other signals detectable by the visually impaired upon contact with path areas.

Since the eyes as sensory organs for the detection of the environment completely or partially disappear in the visually impaired, often the other sensory organs are particularly sensitive. Also, the sense of touch is regularly pronounced over the normal. The innovation is based on the principle of giving a visually impaired the opportunity to better understand and grasp his environment. To learn a way, for example, in a building, such as a public authority or a museum, the visually impaired using the device according to the innovation can study the way before he goes into such a building. He glides with his Finger over the touch-sensitive area. The device always vibrates when the finger is on the path of the path model. Of course, instead of or together with the vibration, it is also possible to generate other signals that can be detected by the visually impaired, such as acoustic signals. In this way, the visually impaired can memorize the way. By repeatedly scanning the path on the route model, the visually impaired finally knows how the path is shaping.

Another aspect of the innovation is that now a positioning system is provided which signals the current location of the device in the path model by vibration. Of course, if the device according to the invention is also used outdoors, it can also help with orientation if a signal of a positioning system, such as the satellite-based GPS, can be detected. In buildings, if necessary, the current location can be determined via Wifi in a cross bearing.

An advantageous embodiment of the inventive electronic device for learning a way for the visually impaired also results from the fact that generates different vibration sequences and / or vibration intensities for different path conditions of the simulation mechanism. At various waypoints, such as stairs, intersections, elevators or dead ends, the visually impaired can be told about the vibration alone, which awaits him there at a certain waypoint.

In a further advantageous embodiment of the inventive electronic device for learning a way for the visually impaired, the electronic device is designed as a smartphone. Smartphones are now everyday tools in all situations. Smartphones have a touch-sensitive surface and a vibration mechanism. In this respect, the device according to the invention can be perfectly realized with such everyday objects as the smartphone.

As an advantageous embodiment of the innovation has also been found when the device generates acoustic information or signals at certain points of the path model. Here, the electronic device can already provide the visually impaired information acoustically, which will expect him on the way.

Further embodiments and advantages will become apparent from the subject of the dependent claims and the drawings with the accompanying descriptions. Embodiments are explained below with reference to the accompanying drawings. The innovation should not be limited solely to these listed embodiments. Rather, embodiments are also considered, which now and in the future in an equivalent manner to the skilled person with other technical aids.

Short description of the drawing

1 shows an inventive electronic device for learning a way for the visually impaired.

Preferred embodiment

In 1 will with 10 an electronic device for learning a way for the visually impaired called. The device comprises a housing 12 with a touch-sensitive surface 14 , The touch-sensitive surface 14 is designed inductively in the present embodiment. In the case 12 is an accumulator 16 as a voltage source 18 intended. The voltage source 18 supplies an electronic circuit 20 with electronic components 22 , The electronic circuit 20 includes in particular a processor 24 and a memory 26 , The processor 24 and the memory 26 essentially form a processor-controlled control mechanism 28 the electronic device 10 ,

The mechanisms described above are also given in a smartphone. The present embodiment therefore relates to such a mobile device whose components are not all described in detail, as they are quite familiar to the skilled person.

The processor-controlled control mechanism 28 is with a GPS receiver 30 or other location system coupled. The GPS receiver 30 receives satellite signals, which causes the current position of the electronic device 10 can be determined relatively accurately. The control mechanism 28 further includes an electronic simulation mechanism 32 , The control mechanism 28 , the simulation mechanism 32 and an electronic vibration mechanism 34 work together during operation.

Via an interface 36 This may be an infrared, radio interface or a cable connection, becomes a route model 38 in the store 26 the device 10 loaded. The way model 38 regularly corresponds to a blind guidance system, which is laid, for example, in a building with structured panels for the visually impaired. These structural panels can be felt by the visually impaired with a blind stick. The coherent structural plates form the blind guidance system with which Visually impaired can find their way around better. The structural plates have different meanings. Waypoints such as intersections or stairs are marked separately with the structure plates. The control mechanism 28 projects this path model 38 on the touch-sensitive surface 14 ,

Once a finger, here symbolic as a circle 40 hinted a way 42 of the way model 38 on the touch-sensitive surface 14 touches, vibrates the device 10 , The vibration is caused by the vibration mechanism 34 generated. This is usually a small electric motor that has an imbalance. The vibration mechanism 34 is from the control mechanism 28 driven. The projection of the path model 38 on the touch-sensitive surface 14 is from the simulation mechanism 32 which causes the control mechanism 28 actuated. Instead of the vibration mechanism 34 In principle, other haptic mechanisms can be used, to which a visually impaired person responds.

Touch the finger 40 the touch-sensitive surface 14 next to the path 42 of the way model 38 , so the vibration stays off. A visually impaired user can do so with his finger 40 based on the way model 38 the way 42 to study along. This is the way 42 in one to the way 42 belonging path area 44 set in which the vibration mechanism 34 is still active.

Once waypoints 46 emerge, for example, each is an intersection 48 , stairs 50 , a dead end 52 , an elevator 54 or a toilet 56 , generates the simulation mechanism 32 with the vibration mechanism 34 one for the waypoints 46 each specific vibration sequence. Alternatively to the vibration sequence can also be via a speaker 58 an acoustic information is output.

The visually impaired can by scanning the path model 38 learn the projected environment. This makes it easier for him to follow a selected path later.

Through the positioning system, the GPS receiver 30 , a path can also be felt outside of buildings. The visually impaired can always assign their current location, especially in the open air.

LIST OF REFERENCE NUMBERS

10

electronic device

12

casing

14

touch-sensitive surface

16

accumulator

18

voltage source

20

circuit

22

electronic components

24

processor

26

Storage

28

control mechanism

30

GPS receiver

32

simulation mechanism

34

vibration mechanism

36

interface

38

path model

40

finger

42

path

44

path area

46

waypoints

48

crossing

50

stairway

52

dead end

54

elevator

56

Toilet

58

speaker

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2133663 B1 [0006]

Claims (5)

Electronic device ( 10 ) to learn a way ( 42 ) for the visually impaired, comprising a) a touch-sensitive surface ( 14 ), b) a vibration mechanism ( 34 ), c) a voltage source ( 18 ) for supplying power to electronic components ( 22 ), d) a processor-controlled control mechanism ( 28 ) with a memory ( 26 ) for the digital storage of a path model, characterized by e) an electronic simulation mechanism ( 32 ), which with the control mechanism, the path model on the touch-sensitive surface ( 14 projected, which touches on Wegwege the device vibrates and / or other transmits detectable for the visually impaired signals. Electronic device ( 10 ) to learn a way ( 42 ) for the visually impaired according to claim 1, characterized in that a positioning system ( 30 ), which determines the current location of the device ( 10 ) in the path model ( 38 ) signaled by vibration. Electronic device ( 10 ) to learn a way ( 42 ) for the visually impaired according to one of claims 1 or 2, characterized in that for different waypoints ( 46 ) the simulation mechanism ( 32 ) generates different vibration sequences and / or vibration intensities. Electronic device ( 10 ) to learn a way ( 42 ) for the visually impaired according to one of the preceding claims, characterized in that the electronic device ( 10 ) is designed as a smartphone. Electronic device ( 10 ) for learning a route for the visually impaired according to one of claims 1 to 4, characterized in that a loudspeaker ( 58 ), whereby the device ( 10 ) acoustic information or signals at certain waypoints ( 46 ) of the path model ( 38 ) generated.

Images