Description:FIELD OF THE INVENTION

[0001] The present invention relates to an adaptable resting assistive device that is capable of providing a means to allow an individual to take rest with proper vibrations of pre-defined intensity, in order to wake the individual with gentle vibrations, rather than abruptly disturbing during sleep after a certain duration.

BACKGROUND OF THE INVENTION

[0002] Resting plays an important role in allowing our bodies and minds to recharge and recover from daily activities. It is essential for overall health and well-being, helping to improve cognitive function, mood, and physical performance. Without proper rest, individuals may experience increased stress, decreased productivity, and a higher risk of developing chronic health conditions. Prioritizing rest can lead to better focus, energy levels, and overall quality of life. Incorporating rest into our daily routines can also help prevent burnout and improve our ability to handle challenges and obstacles effectively. It is important to listen to our bodies and give them the rest they need in order to function at their best. By allowing ourselves to rest and recharge, we can ensure that we are able to maintain a healthy balance in our lives and continue to thrive in all aspects. Making rest a priority ultimately lead to a more fulfilling and sustainable lifestyle.

[0003] Traditionally, the user uses tools for resting that includes pillows, blankets, and mattresses to ensure a comfortable sleeping experience. Additionally, some may also utilize sleep aids such as white noise machines or aromatherapy diffusers to enhance relaxation and promote better rest. These tools help to create a calming environment conducive to sleep by blocking out external disturbances and creating a soothing atmosphere. Experimenting with different combinations of tools help individuals to find the most effective way to improve their sleep quality but faces problems such as stress balls, fidget spinners, or mindfulness apps to help alleviate tension and promote relaxation in providing a quick and easy way to manage stress and improve overall well-being.

[0004] US7909406B2 discloses an invention disclosed herein is securely supported resting apparatus that includes a resting platform sufficient to support the leaning weight of the user and a configuration of straps to provide support in a limited or enclosed space. Although, US’406 provides way to support user in resting by resting platform sufficient to support the leaning weight of the user and a configuration of straps to provide support in a limited or enclosed space, however above cited device lacks in authenticating the user for giving access to utilize the device for resting.

[0005] US6305039B1 discloses a resting system comprising a support for supporting a resting means on which a body can rest in relative comfort, wherein a support means is provided comprising a support frame having a plurality of channel forming means and further wherein the resting means includes a number of components and the junction between at least two of the components provides a further channel, aligned with the channel forming means, so that a securing/restraining means is able to move in the aligned channels; and at least one securing/restraining means including a portion which is adapted to move along the aligned channels and a portion which can be placed against a body to be secured/restrained so as to prevent excessive movement of the body; a kit for the adaptation of existing support means so as to provide the resting system; the use of the resting system in patient care in orthopaedics, neurology, neurosurgery, radiography, radiotherapy, general surgery, rheumatology, physiotherapy, veterinary medicine/surgery, post-operative recovery, by the rescue and emergency service, the armed forces, sports medicine, or during care of the elderly both at home and in nursing homes; and particularly the use for the avoidance of pressure development or the development of pressure sores. Though, US’039 provides way to support a resting means on which a body can rest in relative comfort for patient care in orthopaedics, neurology, neurosurgery, radiography, radiotherapy, general surgery, rheumatology, physiotherapy, veterinary medicine/surgery, post-operative recovery, however above cited devices lacks in spraying a fragrance solution for eliminating the unpleasant smell in surrounding of the resting means.

[0006] Conventionally, many devices are disclosed in prior art that provides way to allow the user to take rest but lacks in promoting better blood circulation and reducing pressure on spine along with alarming action during resting experience by the user for waking the user.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a device that is capable of allowing the user to take rest by promoting better blood circulation and reducing pressure on spine along with alarming action during resting experience by the user for waking the user.

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 allowing an individual to take rest with proper vibrations of pre-defined intensity, in order to wake the individual with gentle vibrations, rather than abruptly disturbing during sleep after a certain duration.

[0010] Another object of the present invention is to develop a device that is capable of detecting abnormality in vital health parameters along with blood flow intensity of the individual to notify the individual regarding the inappropriate health condition in view of taking actions accordingly.

[0011] Yet another object of the present invention is to develop a device that is capable of detecting presence of unpleasant smell in surrounding of the device to spray a fragrance solution for eliminating the unpleasant smell.

[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 an adaptable resting assistive device that is capable of enabling the individual to take rest with proper elimination of unpleasant smell in surrounding of the individual for better relaxing experience for a certain duration of nap specified by the individual.

[0014] According to an embodiment of the present invention, an adaptable resting assistive device, comprises of a body constructed with a pair of elliptical plates arranged in parallel orientation with each other, and positioned over a ground surface connected with each other via an extendable L-shaped member, providing a fixed surface for accommodation of an individual, an artificial intelligence-based imaging unit installed on the body to detect body dimensions of the individual, in accordance to which an inbuilt microcontroller actuates an air compressor installed on the body for inflating an inflatable member fabricated over the member for providing a cushion over the member, that provides a comfortable resting experience to the individual, a motorized drawer arrangement is integrated within the member that is actuated by the microcontroller to modulate dimensions of the member, a weight sensor installed on the member for detecting accommodation of the individual inside the body, an extendable curved-flap is configured on apex of the member via a pair of sliding rails to extend along the rails, in view of forming a canopy over the body, a first sensing module mounted on the body for monitoring real-time weather conditions in surrounding of the individual, an exhaust fan is arranged at back-portion of the body and coupled with a vent crafted on the plates and members that is actuated by the microcontroller to develop air circulation inside the body to provide comfortable resting experience, a user-interface installed in a computing unit accessed by the individual for providing input regarding a time period of nap which is saved in a database linked with the microcontroller, a real time clock is integrated with the microcontroller for monitoring and maintaining a real time track.

[0015] According to another embodiment of the present invention, the proposed device further comprises of a vibrating unit integrated on the inflatable member to produce vibrations of pre-defined intensity, in order to wake the individual gentle vibrations, rather than abruptly disturbing during sleep, multiple second sensing modules embedded on the inflatable member for detecting posture of the individual, array of hydraulic actuators arranged beneath the members to extend and retract in synchronous manner in view of modulating inclination of the members with respect to ground surface, a third sensing module mounted on the body for detecting vital health parameters of the individual along with blood flow intensity of the individual, an odor sensor installed on the body for body for detecting presence of unpleasant smell in proximity to the body, an electronic sprayer attached with a chamber installed on inner portion of the body to spray a fragrance solution stored inside the chamber, for eliminating the unpleasant smell, a C-shaped cushioned panels are arranged with frontal portion of the member via a L-shaped horizontal rod, for allowing individual(s) to rest their foot at an inclined angle, promoting better blood circulation and reducing pressure on spine and a battery 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 an adaptable resting 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 an adaptable resting assistive device that is capable of assisting an individual in taking rest with proper relaxation as per duration of nap specified by the individual along with waking the individual with gentle vibrations, rather than abruptly disturbing during sleep.

[0022] Referring to Figure 1, an isometric view of adaptable resting assistive device is illustrated, comprising a body 101 constructed with a pair of elliptical plates 102 arranged in parallel orientation with each other, the plates 102 are connected with each other via an extendable L-shaped member 103, an artificial intelligence-based imaging unit 104 installed on the body 101, an air compressor 105 installed on the body 101, an inflatable member 106 fabricated over the member 103, an extendable curved-flap 107 configured on apex of the member 103 via a pair of sliding rails 108, a vent 109 crafted on the plates 102 and members 103, a motorized drawer arrangement 110 integrated within the member 103, an electronic sprayer 111 attached with a chamber 112 installed on inner portion of the body 101 and a C-shaped cushioned panels 113 arranged with frontal portion of the member 103 via a L-shaped horizontal rod 114.

[0023] The proposed device comprises of a body 101 encased with all components associated with the device and constructed with a pair of elliptical plates 102 arranged in parallel orientation with each other to provide a fixed surface to accommodate an individual. Upon position of the body 101 over a ground surface, the individual activates the device, manually by pressing a switch button to activate the device manually by pressing a push button integrated on 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 individual, the circuits get closed and starts conduction of electricity that tends to activate the device and vice versa.

[0024] After activating of the device by the individual, a microcontroller associated with the device generates a commands to operate the device accordingly. Upon activating the device, the user accesses a biometric sensor integrated with the body 101 to give fingerprint details for authentication. The biometric sensor used herein is preferably a R307 (optical) biometric sensor, which consists of touch sense pad in contact with prism type glass block where the student’s positioned the finger, image sensor parallel to the pad, LED (light-emitting-diode) emits light towards the glass block and the sensing unit, wherein the R307 biometric sensor works on the principle of TIR (Total Internal Reflection).

[0025] The LED emits the light in a continuous manner towards the glass block at a certain angle for the TIR to occur, when the user position the finger over the touch sense pad, a small amount of the light is leaked to the external medium and it’s called the evanescent wave. While positioning of the finger over the touch sense pad by the user’s, the ridges of the individual’s finger make a good contact with the block and the valley remain separated from the surface by air packets from the block, the alteration of the light is measured by the image sensor. The image sensor processes the details and produce a high-contrast image which is a digital form of the individual’s fingerprint. Further, the sensing unit transmits the details to a microcontroller paired with the sensor. The microcontroller upon receiving and processing the acquired details regarding the individual’s finger and fetch data from a server linked with the microcontroller regarding the individual fetched biometric impressions.

[0026] Based on the fetched biometric impression, if the fetched biometric mismatches with the pre-fed impression, the microcontroller activates an artificial intelligence based imaging unit 104 integrated with the body 101 to detect dimension of the individual’s body. The imaging unit 104, disclosed herein comprises of a camera and processor that works in collaboration to capture and process the images in a 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.

[0027] 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. 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 104 processes the captured images by using a protocol of artificial intelligence to retrieve data from the captured image in the form of digital signal. The detected data is now transmitted to the microcontroller based on which the microcontroller acquires the data to detect the dimension of the individual’s body.

[0028] After detecting the dimension of the individual’s body, the microcontroller generates commands to actuate a motorized drawer arrangement 110 integrated within the member 103 to modulate dimensions of the member 103 as per detected dimension of the individual’s body. The drawer arrangement 110 comprises of a carriage assembly and a DC (direct current) motor that works in collaboration to extend and retract the member 103. The carriage assembly fitted with two rails that are used for sliding the block up and down. The block opening located at the end of the rail and have two clips that are used to secure the member 103. To extend the drawer, the drawer is pushed to open and the carriage assembly slide outward. This creates an opening to allow extension and retraction of the member 103 as per detected dimension of the individual’s body.

[0029] Simultaneously, the microcontroller actuates an air compressor 105 integrated with the body 101 for inflating an inflatable member 106 assembled over an extendable L-shaped member 103 connected between the plates 102 for providing a cushioning effect over the member 103. The air compressor 105 comprises of a motor, an inlet and outlet valve, and a pump. The air of surroundings of the member 106 enters from the inlet valve to compressed and pumped into the member 106. The volume of air then reduced by a mechanical equipment powered by the motor. When the pressure reaches a certain level, then the compressor 105 shut off automatically. Further, the collected pressurized air is passed through the outlet valve to exit out accordingly within the member 106 for inflating the member 106 to provide a cushioning effect in the member 106 that provides a comfortable resting experience to the individual.

[0030] After the inflating of the member 106, the individual gets accommodate inside the body 101 as detected via a weight sensor, wherein the weight sensor comprises a weight transducer that convert weight of the individual into an electrical signal that exert a downward force on the weight sensor. Within load cell of the sensor, there are strain gauges that deform slightly due to weight. The deformation causes changes in electrical resistance within the strain gauges. The sensor then calibrates the resistance to detect weight of the individual. After that the sensor transmitted he detected data to the microcontroller where it analyzes to detect the accommodation of the individual inside the body 101.

[0031] After the detection of the individual inside the body 101, the microcontroller generates commands to actuate a pneumatic unit integrated with an extendable curved- flap 107 is configured on apex of the member 103 via a pair of sliding rails 108 to extend along the rails 108. 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 flap 107. 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.

[0032] 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 flap 107 along the rails 108 for forming a canopy over the body 101.

[0033] During formation of the canopy, a first sensing module mounted on the body 101 for monitoring real-time weather conditions in surrounding of the body 101. The first sensing module includes a temperature sensor and humidity sensor for detecting real-time weather conditions in the surrounding. The temperature sensor operates based on the principle of detecting infrared radiation emitted by the surrounding.

[0034] The temperature sensor comprises crucial components such as an infrared sensor, an optical arrangement, and a detector. It functions on the principle of detecting infrared radiation emitted by the surrounding. When the surrounding’s temperature exceeds absolute zero, it emits infrared radiation. The sensor captures this radiation using its optical arrangement, directing it onto a detector. Common detectors, like thermopiles or pyroelectric sensors, then convert the received infrared energy into an electrical signal.

[0035] The formed electrical signal undergoes processing by electronic components, translating it into a temperature reading of the surrounding. Further, the humidity sensor detects humidity in the surroundings. The humidity sensor works by using a special material that changes its electrical properties as it absorbs moisture from the surrounding. This change is measured and used to determine the humidity level in the sensor. After the detection of the temperature and humidity level in the surrounding, the sensing module transmitted the detected data to the microcontroller where it analyses to detect the real-time weather conditions in the surrounding.

[0036] Upon detecting the weather conditions of the individual, the microcontroller actuates an exhaust fan integrated at back-portion of the body 101 and coupled with a vent 109 assembled on the plates 102 and members 103 to develop air circulation inside the body 101. The exhaust fan works by creating negative pressure within a space, drawing out stale air and odors and expelling the air outside. This process helps to improve air circulation and maintain indoor air quality inside the body 101 to provide comfortable resting experience. During resting experiences, the individual accesses a user-interface installed in a computing unit to give input commands regarding a time period of nap.

[0037] The computing unit, herein includes but not limited to a mobile and laptop that comprises a processor where the input in the user’s interface is received and 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 user’s interface and the device for processing the input given by the individual.

[0038] Upon processing the input given by the individual, the microcontroller actuates a real time clock integrated with the microcontroller for detecting and maintaining a real time track of the nap. The real time clock comprises of pre-set timing due to which the clock starts tracking the timing due to supply of electric signal through the microcontroller. After then the module vibrates to drop a specified time to show the time duration in real time. Based on detection, if the tracked time matches with a pre-fed time duration of nap, then the microcontroller generates commands to actuate a vibrating unit integrated on the inflatable member 106 to produce vibrations of pre-defined intensity to wake the user with gentle vibrations.

[0039] The vibrating unit works by converting electrical energy into mechanical energy which causes the unit to vibrate. The unit comprises of a motor, eccentric weight and shaft, as the microcontroller directs the motor the shaft rotates which in turn rotates the weight. The rotation of weigh creates the unbalanced forces which leads in vibration of the unit resulting in the providing vibrational sensations in the member 103 to wake the user gentle vibrations instead of abruptly disturbing during sleep.

[0040] Additionally, during resting, multiple second sensing modules integrated in the inflatable member 106 detects posture of the individual. The sensing module includes pressure sensor and a gyroscopic sensor that work together to detect the posture of the individual. The pressure sensor detects the pressure applied by the individual in aligning the body 101. The pressure sensor works based on the principle of varying capacitance. The diaphragm acts as one plate of a capacitor, and the pressure-induced deformation changes the distance between the plates 102, thus altering the capacitance. The change in capacitance is then measured and converted into an electrical signal. The electrical signal produced by the transduction mechanism is weak or in a non-optimal format for further processing.

[0041] The processed electrical signal is provided the pressure applied by the individual in aligning the body 101. Further, the gyroscopic sensor detects the alignment of the individual’s body. The gyroscopic sensor works by utilizing the principles of angular momentum to detect changes in orientation. It consists of a spinning mass that resists changes in direction, allowing it to accurately measure rotation and tilt of the individual. Upon detection of the alignment and the pressure of the individual, if the microcontroller finds incorrect posture, then the microcontroller regulates actuation of a hydraulic unit integrated with array of hydraulic actuators integrated beneath the members 103 to extend and retract. The hydraulic unit comprises of an oil reservoir, pump, cylinders, valves and piston that works in collaboration to aid in extension and retraction of the actuators.

[0042] The valve opens and the compressed fluid 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 fluid pressure, the piston extends. For the retraction of the piston, air is released from the cylinder to the pump. Thereby provide extension and retraction of the actuators in sequential manner that aids in modulating inclination of the members 103 with respect to ground surface for correcting posture of individual during sleep.

[0043] Additionally, a third sensing module is integrated with the body 101 detects vital health parameters of the individual along with blood flow intensity of the individual. The third sensing module includes a FBG (Fiber Bragg Grating) sensor, heart rate sensor, temperature sensors and a PPG (Photoplethysmography) sensor that works in collaboration to detect the vital health parameters of the individual along with blood flow intensity of the individual. The FBG The sensing module includes a FBG (Fiber Bragg Grating) sensor that emits an incident IR (Infrared) light from the optical fiber core having a pattern of multiple reflection points. The distance travelled by the IR (Infrared) light between the reflection points of a fiber Bragg grating is always equal.

[0044] The wavelength of IR (Infrared) light that matches exactly with the distance between two reflection points gets reflected by the grating and the other wavelengths that are transmitted through the grating are damped. The sensor further convert distance data into electric signal and transmitted to the microcontroller. The microcontroller process and analyze the signal to detect health parameters of the individual. Further, the PPG (Photoplethysmography) sensor comprises of a pulse sensing element that measure the volumetric pulsations of the blood in tissue of the back portion by emitting an infrared light on the portion of the individual.

[0045] After that the reflected rays calibrate to measures the volumetric pulsation of the blood in order to detect the blood flow rate in the individual. Further, the heart rate sensor works by detecting the electrical signals produced by the heart each time it beats. These signals are then converted into a digital signal that are being interpreted by the sensor for allowing for real-time monitoring of heart rate of the individual. The temperature sensor operates based on the principle of detecting infrared radiation emitted by the individual. The contactless temperature sensor comprises crucial components such as an infrared sensor, an optical arrangement, and a detector. It functions on the principle of detecting infrared radiation emitted by the individual.

[0046] During emission of the radiation, if the individual’s temperature exceeds absolute zero, then it emits infrared radiation. The sensor captures this radiation using its optical arrangement, directing it onto a detector. Common detectors, like thermopiles or pyroelectric sensors, then convert the received infrared energy into an electrical signal. This signal undergoes processing by electronic components, translating it into a temperature reading of the individual.

[0047] Based on detecting health parameters of the individual along with blood flow intensity of the individual, if the detected parameters as well as the blood flow intensity mismatches with a threshold limit, then the microcontroller transmits an alert notification to the computing unit to alert notification regarding the abnormal health conditions. Herein, a C-shaped cushioned panels 113 are assembled with frontal portion of the member 103 by a means of a L-shaped horizontal rod 114 to aid the individual(s) to rest the individual’s foot at an inclined angle for better blood circulation and reducing pressure on spine.

[0048] Additionally, an odor sensor integrated with the body 101 for detecting presence of unpleasant smell in proximity to the body 101. The odor sensor works by detecting and analysing the volatile organic compounds (VOCs) released from the body 101. These VOCs are emitted as gases and carry specific odor molecules that is being identified by the sensor. The sensor consists of a sensitive material that interacts with the VOCs, causing a change in its electrical properties, which is then measured and interpreted to determine the odor of the body 101 and detect presence of unpleasant smell in proximity to the body 101.

[0049] After detection of unpleasant smell, the microcontroller actuates an electronic sprayer 111 integrated with a chamber 112 assembled on inner portion of the body 101 to spray a fragrance solution from the chamber 112 for eliminating the unpleasant smell from the body 101. The electronic sprayer 111 comprises of nozzle, pump, flow control that works in collaboration to spray the water. The working principle of the sprayer 111 is based on the Bernoulli’s principal to flow the water passes through the control flow that maintain the flow of water towards the nozzle. Further, the nozzle dispenses the solution in the body 101 by forming a mist in the form of spray. The nozzle comprises of a magnetic plunger that is activated by the microcontroller to open to dispense the solution in the body 101 to eliminate the unpleasant smell.

[0050] Lastly, 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.

[0051] The present invention works best in following manner that possesses the body 101 constructed with the pair of elliptical plates 102 arranged in parallel orientation with each other, and positioned over a ground surface where the plates 102 are connected with each other via the extendable L-shaped member 103, providing a fixed surface for accommodation of an individual. Herein, the artificial intelligence-based imaging unit 104 detects body 101 dimensions of the individual, in accordance to which the inbuilt microcontroller actuates the air compressor 105 for inflating an inflatable member 106 fabricated over the member 103 for providing a cushion over the member 103 that provides a comfortable resting experience to the individual. Also, the weight sensor detects accommodation of the individual inside the body 101 based on that the extendable curved- flap 107 is actuated by the microcontroller to extend along the rails 108, in view of forming a canopy over the body 101. Further, the first sensing module detects real-time weather conditions in surrounding of the body 101, in accordance to which the microcontroller evaluates a required condition to be maintained inside the body 101 based on that the microcontroller actuates the exhaust fan coupled with a vent 109 crafted on the plates 102 and members 103 that is actuated by the microcontroller to develop air circulation inside the body 101 to provide comfortable resting experience. Also, the user-interface installed in a computing unit accessed by the individual for providing input regarding a time period of nap which is saved in a database linked with the microcontroller based on that the real time clock detects a real time track and if the detected time matches with a pre-fed time duration of nap the microcontroller actuates the vibrating unit to produce vibrations of pre-defined intensity, in order to wake the user gentle vibrations, rather than abruptly disturbing during sleep. Further, upon detection of incorrect posture via the second sensing modules, then the microcontroller regulates actuation of array of hydraulic actuators to extend and retract in synchronous manner in view of modulating inclination of the members 103 with respect to ground surface, and thereby facilitating in correcting posture of individual during sleep. Additionally, the third sensing module detects vital health parameters of the individual along with blood flow intensity of the individual, and in case detected parameters as well as the blood flow intensity mismatches with a threshold limit, then the microcontroller transmits to the computing unit accessed by the individual for notifying regarding he abnormal health parameters along with the blood flow rate.

[0052] 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) An adaptable resting assistive device, comprising:

i) a body 101 constructed with a pair of elliptical plates 102 arranged in parallel orientation with each other, and positioned over a ground surface, wherein said plates 102 are connected with each other via an extendable L-shaped member 103, providing a fixed surface for accommodation of an individual;
ii) an artificial intelligence-based imaging unit 104 installed on said body 101 and paired with a processor for capturing and processing multiple images of surroundings, respectively to detect body 101 dimensions of said individual, in accordance to which an inbuilt microcontroller actuates an air compressor 105 installed on said body 101 for inflating an inflatable member 106 fabricated over said member 103 for providing a cushion over said member 103, that provides a comfortable resting experience to said individual;
iii) a weight sensor installed on said member 103 for detecting accommodation of said individual inside said body 101, wherein an extendable curved- flap 107 is configured on apex of said member 103 via a pair of sliding rails 108, and post successful accommodation of individual inside said body 101, said microcontroller actuates said flap 107 to extend along said rails 108, in view of forming a canopy over said body 101;
iv) a first sensing module mounted on said body 101 for monitoring real-time weather conditions in surrounding of said body 101, in accordance to which said microcontroller evaluates a required condition to be maintained inside said body 101, wherein an exhaust fan is arranged at back-portion of said body 101 and coupled with a vent 109 crafted on said plates 102 and members 103 that is actuated by said microcontroller to develop air circulation inside said body 101 to provide comfortable resting experience;
v) a user-interface installed in a computing unit accessed by said individual for providing input regarding a time period of nap which is saved in a database linked with said microcontroller, wherein a real time clock is integrated with said microcontroller for monitoring and maintaining a real time track and in case said monitored time matches with a pre-fed time duration of nap said microcontroller actuates a vibrating unit integrated on said inflatable member 106 to produce vibrations of pre-defined intensity, in order to wake said individual gentle vibrations, rather than abruptly disturbing during sleep;
vi) plurality of second sensing modules embedded on said inflatable member 106 for detecting posture of said individual, wherein upon detection of incorrect posture, said microcontroller regulates actuation of array of hydraulic actuators arranged beneath said members 103 to extend and retract in synchronous manner in view of modulating inclination of said members 103 with respect to ground surface, and thereby facilitating in correcting posture of individual during sleep; and
vii) a third sensing module mounted on said body 101 for detecting vital health parameters of said individual along with blood flow intensity of said individual, wherein in case detected parameters as well as said blood flow intensity mismatches with a threshold limit, said microcontroller transmits an alert notification to a computing unit accessed by said individual.

2) The device as claimed in claim 1, wherein a motorized drawer arrangement 110 is integrated within said member 103 that is actuated by said microcontroller to modulate dimensions of said member 103, based on said detected body 101 dimensions of individual.

3) The device as claimed in claim 1, wherein said first sensing module includes a temperature sensor and humidity sensor.

4) The device as claimed in claim 1, wherein said second sensing module includes a pressure sensor and a gyroscopic sensor.

5) The device as claimed in claim 1, wherein said third sensing module includes a FBG (Fiber Bragg Grating) sensor, heart rate sensor, temperature sensors and a PPG (Photoplethysmography) sensor.

6) The device as claimed in claim 1, wherein an odor sensor is installed on said body 101 for body 101 for detecting presence of unpleasant smell in proximity to said body 101, and upon detection of unpleasant smell, said microcontroller actuates an electronic sprayer 111 attached with a chamber 112 installed on inner portion of said body 101 to spray a fragrance solution stored inside said chamber 112, for eliminating said unpleasant smell.

7) The device as claimed in claim 1, wherein a C-shaped cushioned panels 113 are arranged with frontal portion of said member 103 via a L-shaped horizontal rod 114, for allowing individual(s) to rest their foot at an inclined angle, promoting better blood circulation and reducing pressure on spine.

8) 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.