Description:FIELD OF THE INVENTION

[0001] The present invention relates to a modular plant watering assistive device that is capable of providing a means to assist a user in watering plant by a water pipe with proper guidance in pouring required amount of water around the plant in order to maintain growth of the plant in ease.

BACKGROUND OF THE INVENTION

[0002] Plants play an important role in providing oxygen, food, and medicine for humans and animals. Plants also play a crucial role in maintaining the balance of ecosystems by absorbing carbon dioxide and releasing oxygen through photosynthesis. Furthermore, plants help regulate the water cycle by absorbing and releasing water vapour through transpiration. Additionally, they provide habitats and food sources for various organisms, contributing to biodiversity and overall ecosystem health. Proper watering helps plants absorb nutrients and maintain turgidity, preventing wilting and dehydration. Additionally, watering also help regulate the temperature of the plant and protect it from extreme weather conditions. Overwatering, however, can lead to root rot and other issues, so it is important to find the right balance. It is recommended to water plants in the morning or evening to minimize evaporation and ensure maximum absorption.

[0003] Traditionally, the user uses irrigation systems that is being programmed to deliver water at specific times and amounts, as well as self-watering help to ensure that plants receive consistent and adequate hydration, promoting healthy growth and reducing the risk of over or under-watering. Additionally, some plant watering devices use sensors to detect moisture levels in the soil and automatically deliver water when needed but the set up for such devices are manually done by skilled persons to regulate water facilities but lacks in removing extra logged water due to which there is chances of improper growth of the plant. So, there needs to develop a device that assist the user in watering the plant.
[0004] US20070089365A1 discloses a plant watering system particularly suited for use in watering indoor, potted plants, includes a plurality of plant watering devices and a main controller. Each plant watering device including a fluid reservoir, a fluid outlet from which fluid may be dispensed to an adjacent plant, and an electronically controlled flow controller controlling the flow of fluid from the reservoir to the outlet. The main controller includes a user input and a control unit configured to generate watering device control signals. Control signals are transmitted from the main controller to each watering device wirelessly. Although, US’365 provides way to watering plants by using a fluid reservoir, a fluid outlet from which fluid may be dispensed to an adjacent plant, and an electronically controlled flow controller controlling the flow of fluid from the reservoir to the outlet, however lacks in guiding the user regarding amount of water to be poured around the plant.

[0005] US3758987A discloses an automatic plant watering device responsive to the plant’s need for water is disclosed. The new watering device includes a porous sensing element that is inserted into the soil and responds to the moisture content of the soil to control the supply of water from a substantially airtight enclosure. The porous element constitutes an air valve. When the soil is relatively dry, air flows through the porous element, and water is released from the enclosure to the soil. When the soil is wet, air cannot pass through the sensing element and the flow of water is automatically shut off. The invention is also directed, in part, to a novel sensing and control device for incorporation in an automatic plant watering device or system. The device uses a basically new principle of operation and has no moving parts. Although, US’987 provides way to watering plants by using a porous sensing element that is inserted into the soil and responds to the moisture content of the soil to control the supply of water from a substantially airtight enclosure, however lacks in recognizing level of the water poured within the enclosed and removing the extra water from the enclosure.

[0006] Conventionally, many devices are disclosed in prior art that provides a way to water plant by guiding the user regarding amount of water to be poured, but lacks in adjusting the device properly with alignment of the plant. Moreover, such devices also lack in removing extra water from the poured region of the plant.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a device that needs to be capable of assisting a user in watering plant by guiding the user regarding amount of water to be poured along with adjusting the device properly with alignment of the plant without causing any mismanagement.

OBJECTS OF THE INVENTION

[0008] The principal object of the present invention is to overcome the disadvantages of the prior art.

[0009] An object of the present invention is to develop a device that is capable of assisting a user in watering plant by a water pipe on the plant by guiding the user regarding amount of water to be poured around the plant in view of maintaining growth of the plant in ease.

[0010] Another object of the present invention is to develop a device that is capable of detecting level of the water poured within the enclosed space for detecting amount of water poured inside the space to remove extra water.

[0011] Yet another object of the present invention is to develop a device that is capable of adjusting the device by aligning the device properly around the plant for properly collecting water around the plant.

[0012] The foregoing and other objects, features, and advantages of the present invention will become readily apparent upon further review of the following detailed description of the preferred embodiment as illustrated in the accompanying drawings.

SUMMARY OF THE INVENTION

[0013] The present invention relates to a modular plant watering assistive device that is capable of watering plant by a water pipe on the plant by guiding the user regarding amount of water to be poured around the plant in view of maintaining growth of the plant.

[0014] According to an embodiment of the present invention, a modular plant watering assistive device, comprises of a curved-shaped body constructed with multiple curved-shaped extendable plates, developed to be positioned in proximity to a plant, an artificial intelligence-based imaging unit is installed on the body to determine dimensions of the plant, multiple motorized hinges configured between the plates for tilting the plates towards/away from each other in view of securing the body around the plant, multiple electromagnets integrated at ends of the plates that are energized by the microcontroller to establishing the body around the plant, a Hall Effect sensor is configured on the plates to detect intensity of magnetic field generated by the electromagnets, an optical sensor configured on the body and synced with the imaging unit to detect alignment of the device based on position of the plant, multiple motorized wheels are arranged underneath the body to maneuver the body over ground surface, a telescopically operated rod attached in between each of the wheels and body to stabilize the platform over the surface during motion for adjusting/ shifting position of the body in view of aligning the body properly around the plant, multiple pneumatic pins configured on bottom portion of the body to extend towards ground surface in view of inserting the pins on the surface for stabilizing the body around the plant.

[0015] According to another embodiment of the present invention, the proposed device further comprises of a tactile sensor is configured on the pins to detect hardness of the surface, a color sensor configured on the body and synced with the imaging unit to detect type of plant enclosed by the body, a moisture sensor configured on the body to detect the moisture content of the soil, a speaker mounted on the body to produce voice alerts for guiding the user regarding amount of water to be poured around the plant and with the enclosed area of body, a computing unit accessed by the user for notifying the user regarding the low moisture content of soil, a motorized clamping unit is configured on the plate for allowing the user to accommodate a water pipe over the clamping unit, in order to facilitate the user in holding the water pipe during pouring of water over the plant, and a battery is associated with the device for powering up electrical and electronically operated components associated with the device.

[0016] While the invention has been described and shown with particular reference to the preferred embodiment, it will be apparent that variations might be possible that would fall within the scope of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings where:
Figure 1 illustrates an isometric view of a modular plant watering assistive device.

DETAILED DESCRIPTION OF THE INVENTION

[0018] The following description includes the preferred best mode of one embodiment of the present invention. It will be clear from this description of the invention that the invention is not limited to these illustrated embodiments but that the invention also includes a variety of modifications and embodiments thereto. Therefore, the present description should be seen as illustrative and not limiting. While the invention is susceptible to various modifications and alternative constructions, it should be understood, that there is no intention to limit the invention to the specific form disclosed, but, on the contrary, the invention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention as defined in the claims.

[0019] In any embodiment described herein, the open-ended terms "comprising," "comprises,” and the like (which are synonymous with "including," "having” and "characterized by") may be replaced by the respective partially closed phrases "consisting essentially of," consists essentially of," and the like or the respective closed phrases "consisting of," "consists of, the like.

[0020] As used herein, the singular forms “a,” “an,” and “the” designate both the singular and the plural, unless expressly stated to designate the singular only.

[0021] The present invention relates to a modular plant watering assistive device that is capable of assisting a user in watering plant by a water pipe on the plant with guiding the user regarding amount of water to be poured around the plant without pouring any extra water the plant in order to maintain proper growth of the plant.

[0022] Referring to Figure 1, an isometric view of a modular plant watering assistive device is illustrated, comprising a curved-shaped body 101 constructed with multiple curved-shaped extendable plates 102, an artificial intelligence-based imaging unit 103 installed on the body 101, multiple motorized hinges 104 configured between the plates 102, multiple electromagnets 105 integrated at ends of the plates 102, multiple motorized wheels 106 arranged underneath the body 101, a telescopically operated rod 107 attached in between each of the wheels 106 and body 101, multiple pneumatic pins 108 configured on bottom portion of the body 101, a speaker 109 mounted on the body 101, multiple pores 110 configured on the plates 102, and a motorized clamping unit 111 configured on the plate 102.

[0023] The proposed device comprises of a curved-shaped body 101 constructed with multiple curved-shaped extendable plates 102 ranging from 4 to 6 in numbers made up of any material selected from but not limited to metallic material wooden material alike. The body 101 is encased with various components associated with the device arranged in sequential manner that aids in assisting a user in watering plant. Upon positioning of the body 101 in proximity of a plant by the user, the user requires to activate the device manually by pressing a button associated with the device and assembled with the body 101. The button is type of a switch that is internally connected with the device via multiple circuits that upon pressing by the user, the circuits get closed and starts conduction of electricity that tends to activate the device and vice versa. After activating of the device by the user, a microcontroller associated with the device generates a commands to operate the device accordingly.

[0024] Upon activating the device, the microcontroller generates commands to actuate an artificial intelligence-based imaging unit 103 assembled with the body 101 for detecting dimensions of the plant. The imaging unit 103 comprises of a camera and processor that works in collaboration to capture and process the images in vicinity of the body 101. The camera firstly captures multiple images of the vicinity of the body 101, wherein the camera comprises of a body, electronic shutter, lens, lens aperture, image sensor, and imaging processor that works in sequential manner to capture images of the vicinity of the body 101. After capturing of the images by the camera, the shutter is automatically open due to which the reflected beam of light coming from the surrounding due to light is directed towards the lens aperture. After then the reflected light beam passes through the image sensor. The sensor now analyzes the beam to retrieve signal from the beams which is further calibrate by the sensor to capture images of the vicinity of the body 101 in electronic signal.

[0025] Upon capturing images, the imaging processor processes the electronic signal into digital image. When the capturing is done, the processor associated with the imaging unit 103 processes the captured images by using an artificial intelligence protocols to retrieve data from the captured image in the form of digital signal. The data is now transmitted to the microcontroller based on which the microcontroller acquires the data and analyze to detect the dimensions of the plant. After that the microcontroller actuates a pneumatic unit associated with the extendable plates 102 to extend and retract as per detected dimensions of the plants. The pneumatic unit comprises of an air compressor, air cylinder, air valves i.e. Inlet and outlet valve and piston that works in collaboration to aid extension and retraction of the plates 102.

[0026] The air compressor is coupled with a motor that gets activated by the microcontroller to compress the air from surroundings upon entering from the inlet valve to compressed and pumped out via the outlet valve. The air valve allows entry or exit of the compressed air from the compressor. Furthermore, the valve opens and the compressed air enters inside the cylinder thereby increasing the air pressure of the cylinder. The piston is connected to the cylinder and due to the increase in the air pressure, the piston extends. And upon closing of the valve, the compressed air exit out from the cylinder thereby decreasing the air pressure of the cylinder. The increasing and decreasing of the air pressure from the cylinder aids in extension and retraction of the piston that turns in aiding extension and retraction of the plates 102.

[0027] Simultaneously, the microcontroller actuates multiple hinges 104 ranging from 4 to 6 in numbers integrated between the plates 102 for orientating the plates 102 towards and away from each other for securing the body 101 around the plant. The hinge 104 typically refers to a mechanical joint that allows rotational movement around a fixed axis using a motor or actuator which provides the rotational force required to move the hinge 104. The motor is typically controlled by an electronic control unit that regulates its speed and direction. The hinge 104 consists of a hinge mechanism that enables rotation around a fixed axis to orient the plates 102 around the plant to secure the plant.

[0028] After the securing of the plant detected by the microcontroller via the imaging unit 103, the microcontroller generates commands to actuate multiple electromagnets 105 ranging from 4 to 6 in numbers fabricated at ends of the plates 102 for securing the body 101 around the plant. The electromagnet 105 comprises of a conducting coil, when the electric current is passed across the coil that result in generation of the magnetic field around the coil and that results in the generation of the magnetic force due to which the electromagnet 105 gets energized. When the current release, the electromagnet 105 gets de-energized. The energization and de-energization of the electromagnet 105 causes the plates 102 to expand around the plant appropriately.

[0029] During securing the body 101 around the plant, a Hall Effect sensor integrated with the plates 102 detects intensity of magnetic field generated by the electromagnets 105. The Hall effect sensor works by detecting the voltage difference (Hall voltage) generated across a conductor when it is exposed to a magnetic field. As the magnetic field interacts with the current flowing through the conductor, the field exerts a force on the moving charge carriers (such as electrons), causing them to accumulate on one side of the conductor. This results in a voltage difference perpendicular to both the current and the magnetic field. The sensor measures this voltage difference, which is proportional to the strength of the magnetic field. The microcontroller then processes this signal to determine the intensity of the magnetic field generated by the electromagnets 105.

[0030] Additionally, an optical sensor synced with the imaging unit 103 integrated with the body 101 detect alignment of the device. The optical sensor works by detecting light waves and converting them into electrical signals. This is typically done using a photodetector, which measures the intensity of light hitting the sensor and finds deviation in intensity of the light hitting the sensor to determine alignment of the device. The detected data is then transmitted to the microcontroller where it analyzes to detect the alignment of the device based on position of the plant and accordingly actuates multiple motorized wheels 106 ranging from 4 to 6 in numbers configured underneath the body 101 to move the body 101 over ground surface.

[0031] Each of the wheels 106 are coupled with a motor that is activated by the microcontroller to rotate the wheels 106 with specified speed in order to move the body 101 over the surface. Simultaneously, the microcontroller actuates a pneumatic unit associated with atelescopically operated rod 107 assembled between each of the wheels 106 and body 101 for stabilizing the platform over the surface to adjust and shift the position of the body 101 in order to align the body 101 properly around the plant and collect water around the plant appropriately. After positioning of the body 101 around the plant detected by the microcontroller via the imaging unit 103, the microcontroller generates commands to actuate a pneumatic unit associated with multiple pneumatic pins 108 ranging from 4 to 6 in numbers integrated at bottom portion of the body 101 to extend the pins 108 along the ground surface and insert the pins 108 on the surface in order to stabilize the body 101 around the plant.

[0032] During inserting of the pins 108, a tactile sensor integrated with the pins 108 detects hardness of the surface. The tactile sensor comprises a sensing element known as elastomer for sensing the interaction of the pins 108 with the surface. When the sensor is subjected to the interaction, the sensor gets activated and behave like a switch. When the interaction is released, the tactile sensor acts as closed switch to experience the force exerted by the by the pins 108. This force leads to deflection in the elastomer which is measured and converted into an electrical signal. After that the tactile sensor transmits the electric signal to the microcontroller linked with the sensor. The microcontroller now analyzes the signal to detect the hardness of the surface and accordingly regulates actuation of the pins 108 to inserts the pins 108 with an optimum amount of pressure up to a threshold depth pre-fed in the microcontroller.

[0033] During stabilizing the body 101 around the plan, a color sensor synced with the imaging unit 103 integrated with the body 101 detects type of plant enclosed by the body 101. The color senor comprises of a white light emitter and RGB (Red, Green, and Blue) filters that works in synchronously to measure wavelength of the RGB present on the plant. The emitter emits white light towards the plant. After that the sensor activates the filter to measures the wavelength sensitivities to the RGB. Based on the detected intensity of the wavelength, the sensor detects the color of the plant. The detected is further transmitted to the microcontroller to analyze the detected color of the plant and evaluate type of plant. Simultaneously, a moisture sensor integrated with the body 101 detects moisture content in the soil. The moisture sensor works on the principle of measuring electrical conductivity or capacitance by using probes or electrodes that come in contact with the moisture, and the level of moisture affects the electrical properties of the moisture. By analyzing these changes, moisture sensor accurately determine the moisture level in the soil. Based on detection, the sensor transmitted the detected data to the microcontroller where it analyzes to detect the moisture content in the soil. Based on detection, the microcontroller evaluates an amount of water to be filled around the plant.

[0034] Simultaneously, the microcontroller generates commands to activate a speaker 109 assembled with the body 101 for guiding the user regarding amount of water requires o pour around the plant and with the enclosed area of body 101. The speaker 109, herein includes a diaphragm, which is typically made of a lightweight and rigid material like paper, plastic, or metal. It is designed to vibrate and produce sound waves when electrical signals are fed to it. A voice coil (a tightly wound coil of wire) attached with the diaphragm of the speaker 109. The voice coil is suspended within a magnetic gap. When an electrical current flows through the coil, it interacts with the magnetic field produced by the magnet assembly, resulting in a force that moves the coil. The magnet assembly creates a magnetic field within the speaker 109.

[0035] When the electrical signal passes through the voice coil, it generates a magnetic field that interacts with the fixed magnetic field produced by the magnet assembly. As the electrical current varies, the magnetic field produced by the voice coil changes, resulting in the voice coil and attached cone/diaphragm moving back and forth. This movement creates pressure variations in the surrounding air, generating sound waves to generate the audible sound to notify the user regarding amount of water requires to pour around the plant and with the enclosed area of body 101.

[0036] During pouring of the water, a motorized clamping unit 111 integrated on the plate 102 access by the user to accommodate a water pipe on the clamping unit 111 to facilitate the user in holding the water pipe during pouring of water over the plant. The clamping unit 111 comprises a hinge that is activated by the microcontroller to provide back and forth movement to the clamping unit 111 to grip the water pipe during pouring of water over the plant. Herein, a level sensor integrated with the amount of water poured inside the space. The level sensor works emits ultrasonic waves in the space which reflected back of the sensor in order to detect distance travelled by the waves. The distance is further calibrated to detect level of the water poured inside the space. If the detected level of the water exceeds a threshold level pre-fed in a database of the microcontroller, the microcontroller generates commands to actuate multiple iris pores 110 ranging from 4 to 6 in numbers integrated with the plates 102 for removing extra water from the enclosed space. The iris pores 110 are similar to the iris lid that comprises of a ring and blades having multiple protrusion. The ring is constructed with multiple grooves that are linked with the protrusion of the blade. The ring is attached with groove to pull the protrusion within the grooves by the rotation of the ring. The pulling of the protrusions provide movement to the blades for opening and closing of the lid. The ring is installed with the motor that is actuated by the microcontroller for rotating the ring with a specified speed. Based on the actuation, the ring regulates the opening and closing the pores 110 to remove extra water from the space.

[0037] Additionally, if the detected moisture level of the soil recedes a threshold value pre-fed in the database of the microcontroller, the microcontroller sends an alert to a computing unit for notifying the user regarding the low moisture content of soil. The computing unit herein includes but not limited to a mobile and laptop that comprises a processor where the alert received from the microcontroller is stored to process and retrieve the output data in order to display in the computing unit. The microcontroller is wirelessly linked with the computing unit via a communication module which includes but not limited to Wi-Fi (Wireless Fidelity) module, Bluetooth module, GSM (Global System for Mobile communication). The communication module acts as a medium between various electronic unit for establishing communication between the device and the computing unit for notifying the user regarding the low moisture content of soil.

[0038] A battery (not shown in figure) is associated with the device to offer power to all electrical and electronic components necessary for their correct operation. The battery is linked to the microcontroller and provides (DC) Direct Current to the microcontroller. And then, based on the order of operations, the microcontroller sends that current to those specific electrical or electronic components so they effectively carry out their appropriate functions.

[0039] The present invention works best in following manner that includes the curved-shaped body 101 constructed with multiple curved-shaped extendable plates 102, developed to be positioned in proximity to a plant. Herein the artificial intelligence-based imaging unit 103 to determine dimensions of the plant based on that the microcontroller actuates the plates 102 to extend/retract and synchronously actuates the motorized hinges 104 for tilting the plates 102 towards/away from each other in view of securing the body 101 around the plant, followed by actuation of the electromagnets 105 are energized by the microcontroller to establishing the body 101 around the plant. Also, the optical sensor synced with the imaging unit 103 detects alignment of the device based on position of the plant, based on that the multiple motorized wheels 106 to maneuver the body 101 over ground surface, followed by actuation of the telescopically operated rod 107 to stabilize the platform over the surface during motion for adjusting/ shifting position of the body 101 in view of aligning the body 101 properly around the plant for properly collecting water around the plant. Upon successful positioning of the body 101 around the plant, the microcontroller actuates the pins 108 to extend towards ground surface in view of inserting the pins 108 on the surface for stabilizing the body 101 around the plant. Also, the color synced with the imaging unit 103 detects type of plant enclosed by the body 101, and based on which the type of plant and moisture content of soil as detected via the moisture sensor, the microcontroller evaluates an amount of water to be filled around the plant, and simultaneously the microcontroller activates the speaker 109 to produce voice alerts for guiding the user regarding amount of water to be poured around the plant and with the enclosed area of body 101. Also, the level sensor detects level of the water poured within the enclosed space for detecting amount of water poured inside the space, and in case the level of water exceeds a threshold limit, the microcontroller actuates the multiple pores 110 for removing extra water from the enclosed space.

[0040] Although the field of the invention has been described herein with limited reference to specific embodiments, this description is not meant to be construed in a limiting sense. Various modifications of the disclosed embodiments, as well as alternate embodiments of the invention, will become apparent to individuals skilled in the art upon reference to the description of the invention. , Claims:1) A modular plant watering assistive device, comprising:

i) a curved-shaped body 101 constructed with plurality of curved-shaped extendable plates 102, developed to be positioned in proximity to a plant, wherein an artificial intelligence-based imaging unit 103 is installed on said body 101 and integrated with a processor for capturing and processing multiple images in vicinity of said body 101, respectively to determine dimensions of said plant;
ii) an inbuilt microcontroller linked with said processor, wherein based on said detected dimensions of said plant, said microcontroller actuates said plates 102 to extend/retract and synchronously actuates plurality of motorized hinges 104 configured between said plates 102 for tilting said plates 102 towards/away from each other in view of securing said body 101 around said plant, followed by actuation of plurality of electromagnets 105 integrated at ends of said plates 102 that are energized by said microcontroller to establishing said body 101 around said plant;
iii) an optical sensor configured on said body 101 and synced with said imaging unit 103 to detect alignment of said device based on position of said plant, wherein multiple motorized wheels 106 are arranged underneath said body 101 to maneuver said body 101 over ground surface, followed by actuation of a telescopically operated rod 107 attached in between each of said wheels 106 and body 101 to stabilize said platform over said surface during motion for adjusting/ shifting position of said body 101 in view of aligning said body 101 properly around said plant for properly collecting water around said plant;
iv) plurality of pneumatic pins 108 configured on bottom portion of said body 101, wherein upon successful positioning of said body 101 around said plant, said microcontroller actuates said pins 108 to extend towards ground surface in view of inserting said pins 108 on said surface for stabilizing said body 101 around said plant;
v) a color sensor configured on said body 101 and synced with said imaging unit 103 to detect type of plant enclosed by said body 101, wherein based on which said type of plant and moisture content of soil as detected via a moisture sensor configured on said body 101, said microcontroller evaluates an amount of water to be filled around said plant, and simultaneously said microcontroller activates a speaker 109 mounted on said body 101 to produce voice alerts for guiding said user regarding amount of water to be poured around said plant and with said enclosed area of body 101; and
vi) a level sensor configured on said body 101 for detecting level of said water poured within said enclosed space for detecting amount of water poured inside said space, and in case said level of water exceeds a threshold limit, said microcontroller actuates plurality of multiple pores 110 are configured on said plates 102 for removing extra water from said enclosed space.

2) The device as claimed in claim 1, wherein a tactile sensor is configured on said pins 108 to detect hardness of said surface, based on which said microcontroller inserts said pins 108 with an optimum amount of pressure for inserting said pins 108 up to a threshold depth.

3) The device as claimed in claim 1, wherein a Hall Effect sensor is configured on said plates 102 to detect intensity of magnetic field generated by said electromagnets 105, and in case said detected intensity recedes a threshold value, said microcontroller regulates energization of said electromagnets 105 for adjusting said magnetic strength to collect water perfectly inside said body 101.

4) The device as claimed in claim 1, wherein a motorized clamping unit 111 is configured on said plate 102 for allowing said user to accommodate a water pipe over said clamping unit 111, in order to facilitate said user in holding said water pipe during pouring of water over said plant.

5) The device as claimed in claim 1, wherein a moisture sensor is arranged on said plate 102 for detecting moisture content of said soil, and in case said detected moisture content recedes a threshold value, said microcontroller sends a wireless notification on a computing unit accessed by said user for notifying said user regarding said low moisture content of soil.

6) The device as claimed in claim 1, wherein said microcontroller is wirelessly linked with said computing unit via a communication module which includes, but not limited to Wi-Fi (Wireless Fidelity) module, Bluetooth module, GSM (Global System for Mobile Communication) module.

7) The device as claimed in claim 1, wherein a battery is associated with said device for powering up electrical and electronically operated components associated with said device.