Blind Dog Navigation System

Abstract

The present invention relates to a device and a method associated with helping blind dogs navigate. With respect to the device, it is a set of one or more sensors and stimulators, which provide situational awareness to a blind dog regarding objects and sudden drops in its vicinity, helping the dog freely move about without the risk of collision or fall. The core components of the invention are a distance sensor, a microcontroller, a tactile/audio stimulator, an accelerometer, a power source, a control panel, a body harness, and a head wrap, which, generally speaking, are configured as follows: a frontal distance sensor mounted on top of a blind dog's head using the head band, the lower distance sensor, the stimulators, the microcontroller, the accelerometer, the power source, and the control panel are mounted on the blind dog using the body harness. With respect to the associated method, in order to carry out the method the following core steps are followed: a frontal distance sensor method to detect the objects in front of the blind dog and alert the blind dog when a collision is imminent, a drop sensor method to detect sudden drops in front of the blind dog and alert the dog when a fall is imminent, a velocity calibration method and a velocity computation method determine the movements of the dog based on accelerometer signals, and a velocity compensated alert method adjust and increase the alert distance/time when the dog is moving toward an obstacle or a drop.

Claims

1. A blind dog navigation system: a body harness, having pockets, suitable to be worn by a dog in the shoulder and torso region; and a head band, suitable to be worn by the dog over the head and neck region; and a microcontroller located in a pocket of the body harness; and a frontal distance sensor attached to the head band and located on top of the dog's head pointing forward; and a stimulator located in the body harness close to the dog's body; and a power source located in a pocket of the body harness; and a wiring harness located across the body harness and the head band, which connects the microcontroller to the frontal distance sensor, the stimulator, and the power source.

2. The blind dog navigation system according to claim 1, wherein the frontal distance sensor transmits sending wave and receives returning wave signals.

3. The blind dog navigation system according to claim 2, where a lower distance sensor is attached to the front of the body harness between the dog's legs pointing forward and downward and connected to the microcontroller via the wiring harness.

4. The blind dog navigation system according to claim 3, wherein the lower distance sensor transmits sending wave and receives returning wave signals.

5. The blind dog navigation system according to claim 4, wherein a control panel is located in a pocket of the body harness and connected to the microcontroller via the wiring harness.

6. The blind dog navigation system according to claim 5, wherein the control panel is housed within a case.

7. The blind dog navigation system according to claim 6, wherein the control panel has a status light.

8. The blind dog navigation system according to claim 7, wherein the control panel has an On/Off button.

9. The blind dog navigation system according to claim 8, wherein the control panel has a learn button.

10. The blind dog navigation system according to claim 9, wherein the control panel has a reset button.

11. The blind dog navigation system according to claim 10, wherein an accelerometer is located in a pocket of the body harness and connected to the microcontroller via the wiring harness.

12. The blind dog navigation system according to claim 11, wherein the head band has opening for the dog's ears.

13. The blind dog navigation system according to claim 12, wherein the head band is in the form of an adjustable wrap with a fastening mechanism.

14. The blind dog navigation system according to claim 13, wherein the head band's fastening mechanism is a hook and loop.

15. The blind dog navigation system according to claim 14, wherein an accelerometer is located in a pocket of the body harness and connected to the microcontroller via the wiring harness.

16. A blind dog navigation system: a microcontroller; and a frontal distance sensor; and a lower distance sensor; and a stimulator; and an accelerometer; and a power source; and a wiring harness, which connects the microcontroller to the frontal distance sensor, the lower distance sensor, the stimulator, the accelerometer, and the power source; and a logic program operates in the microcontroller.

17. The blind dog navigation system according to claim 16, wherein the frontal distance sensor transmits sending wave and receives returning wave signals.

18. The blind dog navigation system according to claim 17, wherein the lower distance sensor transmits sending wave and receives returning wave signals.

19. The blind dog navigation system according to claim 18, wherein parameters Dmin, Dmax, and Ddrop are stored in the software control logic.

20. The blind dog navigation system according to claim 19, wherein the parameters Dmin, Dmax, and Ddrop are predetermined based on the safety preferences provided by the owner of the dog.

21. The blind dog navigation system according to claim 20, wherein the parameter Dmin indicates the shortest acceptable distance between the dog and an obstacle.

22. The blind dog navigation system according to claim 21, wherein the parameter Dmax indicates the maximum range of the frontal distance sensor.

23. The blind dog navigation system according to claim 22, wherein the parameter Ddrop indicates the shortest distance detected by the lower distance sensor.

24. The blind dog navigation system according to claim 23, wherein the logic program monitors the sending waves and the receiving waves from the frontal distance sensor and the lower distance sensor.

25. The blind dog navigation system according to claim 24, wherein the logic program activates one of the stimulators when the frontal distance sensor detects an obstacle within the Dmax and Dmin range.

26. The blind dog navigation system according to claim 25, wherein the logic program activates one of the stimulators when the frontal distance sensor detects an obstacle within the Dmax and Dmin range and increases the activation signal as Dmin is approached.

27. The blind dog navigation system according to claim 26, wherein the logic program activates one of the stimulators when the lower distance sensor detects an obstacle at the Ddrop limit.

28. The blind dog navigation system according to claim 27, wherein an accelerometer, which is connected to the microcontroller via the wiring harness.

29. The blind dog navigation system according to claim 28, wherein the logic program computes the forward velocity of the dog using the accelerometer input.

30. The blind dog navigation system according to claim 29, wherein the software logic proportionally activates the stimulator driven by the frontal distance sensor as a function of the forward velocity of the dog.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] FIG. 1 shows a dog wearing the present invention.

[0016] FIG. 2 shows the operations of the distance sensors.

[0017] FIG. 3 shows the method for avoiding collisions.

[0018] FIG. 4 shows the method for avoiding sudden drops.

[0019] FIG. 5 shows the control panel.

[0020] FIG. 6 shows the adjusting mechanism for body harness and head band.

[0021] FIG. 7 shows alert velocity compensation at low speed.

[0022] FIG. 8 shows alert velocity compensation at moderate speed.

[0023] FIG. 9 shows alert velocity compensation at high speed.

[0024] FIG. 10 shows a chart of velocity compensated alert.

[0025] FIG. 11 shows the methods for velocity compensated alerts.

DETAILED DESCRIPTION OF THE INVENTION

[0026] The present invention is directed at a system to help blind dogs navigate, and in general help blind dogs receive alternative non-visual signals in regards to object in front of them or drops in their paths. In its most complete form, the present invention device is made up of the following components: a body harness, a head band, a microcontroller, a control panel, a frontal distance sensor, a lower distance sensor, a stimulator, a power source, a wiring harness, and an accelerometer. These components are related to each other as follows: the body harness is worn by the blind dog in the shoulder and torso area, the body harness provides pockets for storing the microcontroller, the power sources, the stimulators, and the wiring harness. The head band is worn over the blind dog's head and neck, and provides a platform for mounting the frontal distance sensor in a forward pointing fashion. The lower distance sensor is mounted on the body harness, in the chest area, and in between the dog's legs, pointing in a front and down fashion. At least one stimulator for each of the aforementioned distance sensors are mounted in the body harness, such that the resultant stimulation is felt by the dog without causing pain or irritation. The power source provides power to the aforementioned components. The aforementioned components are connected to each other via the wiring harness. The control panel has at least a status light, an On/Off button, and a reset button, which are collectively used to allow the owner to interact with the system.

[0027] The most complete form of performing the methods associated with the present invention device is a logic program consisting of the following steps: a frontal sensor method, a drop sensor method, a velocity calibration method, a velocity computation method, and a velocity compensated alert method. The following variables are used by the aforementioned methods: a Dmin, which is the minimum distance to an object in front of the dog and the distance at which the frontal collision alert is at its peak; a Dmax, which is the maximum distance to an object in front of the dog and the distance beyond which there is no risk of collision, hence no frontal collision alert; and a Ddrop, which is the maximum distance from the lower distance sensor to the ground lower than which the blind dog is safe from falling, and any distance larger than Ddrop presents a risk of fall and invokes a drop alert. The frontal sensor method monitors the signals from the frontal distance sensors and provides alerts via the stimulators as a function of Dmin and Dmax, as described below. The drop sensor method monitors the signals from the lower distance sensors and detects any sudden drop in front of the blind dog, when Ddrop is exceeded, and provides an alert via a stimulator, as described below. The stimulators are of any communication modality that would alert the dog, such as vibration, sound, or ultrasound. The distance sensors use any combination of available non-contact distance measuring modality, such as ultrasound, infrared, laser, or optics.

[0028] It should be noted that a period of training and adjustment by the blind dog and the owner is required for the dog to become comfortable with the device, interpret the signals provided by the stimulator, and learn to take appropriate action. Further, the head band and the body harness are made with materials that are comfortable for the blind dog. The head band and the body harness are made in different sizes and can be adjusted to different sized dogs. Still further, the choice of the power source is such that it cannot harm a blind dog, therefore low voltage rechargeable batteries without the risk of explosion are preferred.

[0029] As shown in FIG. 1, a body harness (105) is worn by a dog in the shoulder area, serves a platform for mounting other components, provides pockets for storing various components, and hides any required wiring. The body harness (105) has opening for the dog's front legs. A head band (110) is worn around the dog's head and neck, and serves as a platform for mounting other components. The head band (110) has opening for the dog's ears. Both body harness (105) and head band (110) are designed to be soft, snug, and comfortable for the dog to wear. A microcontroller (115) is mounted on the body harness (105). The microcontroller (115) is a microprocessor and memory capable of executing software instructions. A frontal distance sensor (120) is mounted on the head band (110). The frontal distance sensor (120) is mounted in a forward pointing manner, and provided angular adjustments to the owner so that the sensor element would point forward when the dog holds its head in a natural stance. The function of the frontal distance sensor (120) is to provide the microcontroller (115) with a signal indicating the distance of an object in front of the dog. At least one stimulator (125) is mounted on the body harness (105) and/or the head band (110). In the preferred embodiment, the stimulator (125) provides vibration and/or sound that the dog can sense. The strength of the stimulator is sufficient to alert the dog, but not cause discomfort. A power source (130) provides power all the components in the present invention that require power. In the preferred embodiment the power source is a rechargeable battery. A wiring harness (135) connects the microcontroller (115) and the power source (130) to other components such as the sensors and the stimulators. The wiring harness (135) is preferably tucked into the body harness and not visible. The part of the wiring harness (135) that connects the frontal distance sensor (120) to the microcontroller (110) and the power source (130) has an optional protective sheath; also, the same wire is optionally retractable or attached to the dog's collar to avoid tangling. An optional lower distance sensor (145) is centrally mounted on the body harness (105) between the dog's legs in such a manner that it points forward and downward. The owner can optionally adjust the angle of the lower distance sensor (145) to compensate for the size of the dog and ensure that the sensor points downward and forward. The function of the lower distance sensor (145) is to send a signal to the microcontroller (115) indicating the presence or absence of a sudden drop in front of the dog. An optional control panel (140) is mounted on the body harness (105) to allow the owner to control the device described in the present invention. An optional accelerometer (150) is mounted on the body harness (105), which provides the microcontroller (110) with signals indicating the movements of the dog.

[0030] FIG. 2 illustrates the operation of the frontal distance sensor (120) and the lower distance sensor (145). The distance sensors can use any combination of commonly available non-contact distance measurement techniques, such as ultrasound, infrared, laser, or optics. The distance sensors provide signals to the microcontroller (110) indicating the presence of absence of objects in front of them.

[0031] In the case of the frontal distance finder (120), the sensor emits ultrasound or light sending wave (205) and detect the returning wave (210) after striking and rebounding from an object (205). The timing between the sending wave (205) and the returning wave (210) along a distance vector (225) is used to compute the distance between the frontal distance sensor (120) and the object (200). A Dmin (215) distance is the minimum threshold, and a Dmax (220) distance is the maximum threshold. At Dmin an object is considered to be close enough to touch the dog, and at Dmax an object is considered to be too far to be relevant. Dmin is ideally just in front of the dog's nose, with a default value such as 30 cm, and can be adjusted by the owner using the control panel (140). Dmax is a reasonable distance in front of the dog where objects need to be detected to give the dog a sense of situational awareness. Dmax must be far enough to provide useful information to the dog, but not too far to overwhelm the dog with excessive sensory input by detecting every object in the vicinity. Dmax has a default value such as 100 cm. The signals received from the frontal distance sensor (120) by the microcontroller (110) are used to provide feedback to the dog via the stimulator (125). The dog can sway its head around to gain situational awareness by sensing the objects around it. In the preferred embodiment of the present invention the strength of the stimulator (125) signal associated with the frontal distance sensor (120) is inversely proportional to the distance. The strength of the stimulator can be frequency of vibration or loudness of a sound. Hence, maximum stimulator strength is indicated at Dmin, and minimum strength is indicated at Dmax. No stimulation is provided for objects beyond Dmax.

[0032] In the case of the lower distance sensor (145), the sensor can emit ultrasound or light sending wave (230) and detect the returning wave (235) after striking and rebounding from the surface in front of the dog. The timing between the sending wave (230) and the returning wave (235) is used to compute the distance between the lower distance sensor (145) and the surface in front of the dog. Ddrop (240) is the threshold indicating a sudden drop in front of the dog. A sudden drop (225) causes a substantial increase in distance beyond Ddrop (240), indicating an unsafe drop in the surface elevation in front of the dog. The lower distance indicator (145) sends signal to the microcontroller (110), which in turn activates a stimulator to alert the dog of a sudden drop in front of it. The dimension of Ddrop depends on the size of the dog and the angle of the lower distance sensor (145), and adjusted by the owner using the control panel (140). If the distance to surface in front of the dog is less than Ddrop, then no alert is issued. If the distance increases beyond Ddrop, then the dog is alerted via a stimulator (125) allocated to the lower distance sensor (145).

[0033] The stimulators (125) assigned to the frontal distance sensor (120) and the lower distance sensor (145) are preferably different in nature and located on different parts of the body harness, so that the dog would more easily discern between the alerts and take appropriate action to avoid a collision or fall.

[0034] With reference to FIG. 3, the frontal distance sensor signal (305) is generated by the frontal distance sensor (120), where the signal strength is preferably indicative of the distance between the sensor and an object in front of it. A signal to microcontroller (310) is conveyed via wiring harness (135) to the microcontroller (115). An object within the range defined by Dmin and Dmax (315) is a conditional test of the said signal, where the values for Dmin and Dmax are stored in memory and compared with the incoming signal. If the signal indicates the presence of an object between Dmin and Dmax then a collision is anticipated (320) signal is invoked, which sends a signal to stimulator (325) to alert the dog. If the signal is not between Dmin and Dmax, then nothing happens and the continue monitoring (330) step is invoked to continue measuring distance to nearby objects. In the preferred embodiment, the strength of the signal to the stimulator (125) is inversely proportional to the distance measured by the sensor, such that the signal to the stimulator is at its maximum at Dmin and at its minimum at Dmax, thus the dog has a sense of distance from an object as a function of the strength of the alert provided by the stimulator (125).

[0035] With reference to FIG. 4, the lower distance sensor signal (405) is generated by the lower distance sensor (145). A signal to microcontroller (410) is conveyed via wiring harness (135) to the microcontroller (115). A surface further than Ddrop is tested in the object further than Drop (415) step, which is a conditional test of the said signal. If the signal indicates a distance greater than Ddrop then an alert is issued to the dog via a stimulator (125) indicating a sudden drop directly in front of the dog. If the signal is not less than Ddrop, then nothing happens and the continue monitoring (430) step is invoked to continue measuring distance to nearby surfaces.

[0036] FIG. 5 shows the control panel (140), which is mounted on the body harness (105) and connected to the microcontroller (115) and received power from the power source (130). The control panel is the interface between the present invention and the owner, and used for turns the system on/off, resetting the system, and customizing the settings such as adjusting Dmax and Ddrop values. The control panel (140) has a case (505), a status light (515), and On/Off button (510), and a reset button (520). Optionally, a learn button (525) is also present on the control panel (140). The status light would indicate if the system is on/off, but it would also indicate when alerts are presented to the dog, for example via flashing or changing color. This function is of value during training and monitoring the dog, by informing the owner of the stimuli received by the dog.

[0037] FIG. 6 shows a sample of the body harness (105) and the head band (110). In both cases an adjustable wrap (605) is provided with openings (610) for the dog's front legs or ears. The body harness (105) is sized according to the size of the dog, and further adjustable for a snug fit using two straps with a fastening mechanism (615). In the preferred embodiment of the present invention the fastening mechanism (615) is hook & loop type fastener.

[0038] FIGS. 7, 8, and 9 illustrate the adaptability of the present invention to how fast a dog moves. Dmax is used for the initial detection of an object that presents a risk of collision. At rest or when walking very slowly, Dmax only needs to be a short distance from the dog, for example 100 cm. However, as the dog walks fast or runs, Dmax increases to provide an alert to the dog in sufficient time for it to slow down and stop. Therefore, there is a direct relationship between Dmax and the velocity of the dog. In FIG. 7, the dog is standing, the velocity (705) is zero, and Dmax (710) is a short distance, for example 100 cm. In FIG. 8, the dog is walking fast where the velocity (805) is greater than zero, thus Dmax (810) is longer, for example 150 cm. In FIG. 9, the dog is running fast, the velocity (905) is high, and Dmax (910) has a larger value, for example 300 cm.

[0039] The chart in FIG. 10 shows a linear relationship between velocity of the dog and Dmax. A linear equation for computing Dmax as a function of velocity, using the slope-intercept method, is in the form Velocity=m.Dmax+b, where m is the slope and b is the value of Dmax when the dog is stationary. For example, the equation Velocity=0.6Dmax+100 can be used, which implies Dmax=(Velocity100)0.6. The illustrated values for m and b are illustrative only and they can optionally vary for different dogs and situations. Also, the computation of Dmax is not limited to a linear equation, where non-linear and exponential functions can also be used to compute Dmax from Velocity.

[0040] FIG. 11 shows the method for computing Dmax in the embodiment where Dmax responds to the movement of the dog. Velocity calibration (1105) is a method for computing the velocity of the dog based on the accelerometer (150) is measured along a single axis of movement, for example the X-axis only, indicating a forward motion. The acceleration value provided by the accelerometer (150) can be a positive value, indicating the dog is accelerating, or a negative value, indicating the dog is slowing down. The use of an accelerometer in velocity computation requires an initial state in which a dog is not moving. Therefore, the process begins by the owner holding the dog still, and press the Reset (520) button on the control panel (140). A reset button pressed (1110) step leads to an initialize velocity baseline (1115) step, which sets the current acceleration and velocity values to zero (1120). The velocity calibration (1105) step will have to be repeated from time to time to ensure accurate velocity computation. The accelerometer (150) samples the dog's movements at discrete events, for example every 0.05 second. Since acceleration=change in velocity/change in time, the velocity computation (1125) step calculates the velocity at the said sapling rate and presents the current velocity of the dog. A small threshold value and averaging are used to minimize any noise associated with the accelerometer (150) signals. A Dmax computation (1135) step computes the current Dmax (1140) based on the current velocity computed by velocity computation (1125). An example of such computation is Dmax=(Velocity100)0.6. The Dmax value computed here is used in the object within Dmin and Dmax (315) step illustrated in the method of FIG. 3. Therefore, the dog receives an earlier alert when moving faster, thus being able to run and slow down when approaching an object at a high velocity.

[0041] It should be noted that the use of the present invention requires training. In such training, the dog is exposed to conditions where the stimulator (125) provides an alert, so that the dog would associate the alert with closeness to an object or approaching a sudden drop. This learning association can be rewarded by the owner when the dog avoids a collision of a fall. Such association is commonly known as Pavlovian conditioning, and can require repetition over time if the dog is not exposed to the target conditions, such as running or a facing a sudden drop.

[0042] The present invention has been fashioned for a blind dog, but a person of ordinary skill in the art would recognize that the system is equally applicable to other animals intelligent enough to develop the necessary response to the alerts. For example, blind chimpanzees and horses can also benefit from the present invention. It should be further noted that a person of ordinary skill in the art would also recognize that the wiring harness is replaceable by wireless communication, and a solar panel or an induction device can charge the batteries in the power source (130).

[0043] While the present invention has been described above in terms of specific embodiments, it is to be understood that the invention is not limited to these disclosed embodiments. Many modifications and other embodiments of the invention will come to mind of those skilled in the art to which this invention pertains, and which are intended to be and are covered by both this disclosure and the appended claims. It is indeed intended that the scope of the invention should be determined by proper interpretation and construction of the appended claims and their legal equivalents, as understood by those of skill in the art relying upon the disclosure in this specification and the attached drawings.