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The Mystery Of The Grand Theory Of Heat Waves/ Role Of Autonomous Drones Used In Solar Energy

As we have seen that always there is increasing solar heat in upcoming season Due to increase global warming and poisoness gases in air.AlsoSome time fire catches in forest due to this problem there is a miseffect in wildlife also sometime drought happen in crops field areas due to lack of irrigation.So we have made a plans regarding this problem I have made a model of Autonomous dronesused to reduce summer heat ,crops protection and wildlife preservation.There Are three method of reducing the solar heat like one of those is used by solar pannel, Carbon composite reflector and Autonomous drones etc. These self-governing drones offer a cool supply to the solar panel, which receives heat from the sun, assisting further in lowering the heat trapped in the atmosphere of Earth. During summer, solar panels greatly assist in decreasing atmospheric temperature as they serve as green technologies. Additionally, we utilize carbon composite reflectors covered in a front layer of alumina oxide, which has remarkable blow torch grade heat shield properties. Therefore, if both are used together, they help in sustaining the solar temperature needed during the summertime. Summer seasons have varying locations around the world. With the current low number of drones and solar panels available, it would be beneficial for us to utilize solar panels along with carbon composite reflectors, so it could remarkably aid worldwide coverage. The use of GPS along with prototypes could make this possible. Moreover, the self-governing drones can have solar-powered turbines, which allow flight for extended periods without recharging. They shift from power to standby mode when not in use to prolong operational range, making them excellent for drone-based environmental monitoring, infrastructure surveillance, and even Research Paper of the grand theory of heat. 

Solar Unmanned Aerial Vehicles (UAVs) or solar drones are a remarkable development in the technology of unmanned aerial vehicles. Unlike conventional drones, these autonomous aerial vehicles utilize solar energy, which allows them to remain aloft for extended durations without the need for battery recharges. Therefore, they can efficiently address a variety of tasks, including monitoring the environment, surveillance of infrastructure, and conducting search and rescue operations. With the help of highaltitude range drones, we have to inject very thin cool water vapor so that after completing one cycling, a supercooled atmosphere develops, and these injected droplets water vapor can evaporate in the atmosphere, forming a supercooled atmosphere so that the temperatures can be cooled in summer. These have to be met to sustain solar heat during summer. We need to achieve the dimming of sunrays by either the refraction or reflection phenomenon. The Earth is at aphelion, and its farthest point from the sun in summer. In winter, the Earth is at perihelion, its closest point to the sun. Although the distance difference contributes to the seasons, it is not the main determinant. The main driving factor for the season is the axial tilt of the Earth. It is clear that during Summer Earth is at Aphelion and therefore we receive more sun rays entering the atmosphere. However, in winter, Earth is at Perihelion, the closest point to the sun, which results in fewer rays entering the atmosphere, causing cooling and fog. Therefore, the goal becomes to allow more rays to enter during winter and less in the summer. During summer we try to reflect and dim as much sunlight as possible so the atmosphere cools, while in winter we need to allow more sunlight in to increase the temperature.

 If a company utilizes the looping Method for temperature regulation, it can be quite beneficial. my code is secure and provides results, and changes of season cause no health concerns. The Earth is rotating from the North Pole to the South Pole. During the June solstice (summer), it becomes hot because sunlight (as shown by red arrows) is concentrated in certain regions. From all three figures, it is evident that the Earth rotates in a way that makes the North Pole tilt towards the Sun. The area where the red arrows are shown is experiencing daylight, which clearly means that only those regions are receiving direct sunlight and therefore heat. We don’t need to focus on the entire Earth, just on the areas where the red arrows show sunlight hitting. As Earth rotates and seasons change, this red-arrow zone will shift, and the heat in the previous area will reduce. The changing seasons occur because of the Earth's axial tilt. This means that the areas receiving intense sunlight (indicated by the red arrows) should undergo a refraction process, in which sunlight is dimmed so that only mild light reaches those regions, helping keep the environment stable. In the first figure, when the North Pole is tilted towards the Sun, it is the month of June, and it is summer — hence, it's hot. In the second figure, both the North and South Poles are upright, and this results in equal day and night, called the equinox. In the third figure, the North Pole is tilted away from the Sun, indicating that it is December, hence winter. 

So wherever the red arrow is pointing, we need to implement a refraction process. It is not about Earth's rotation or the rest of the area; the focus should be on managing the heat in the red-arrow zones. We must also create monthly and weekly rainfall in those areas to maintain crop health and avoid damage during high temperatures. If we reduce the intensity of sunlight and provide regular rainfall, everything will remain balanced. All of this must be done in the Earth's surrounding atmosphere. For this, we should use an adjustable transparent black carbon shield mirror, which would be attached to carbon composite satellites. These mirrors should have high scattering properties. 2 From space, we would deploy this system over the red-arrow zones to create diminished sunlight. The black adjustable transparent mirrors should be capable of rotating from 0 to 360 degrees — where 0 degrees means fully closed (no rays passing), and 360 degrees means fully open (all rays passing). We would then adjust the mirror's opening as needed to control how much sunlight reaches Earth. How to cover an area, suppose we take a torch, switch it on, and focus it from a close distance — the light will scatter over a smaller area. But if we shine the light from a greater distance, it will scatter over a larger area. In the same way, we will use an adjustable mirror according to requirements. A black transparent mirror will dim the light and help cover the area. We plan to attach this setup to a carbon composite satellite and use a prototype to cover specific areas by tracking locations. A location sensor will be installed in the satellite, and it should be equipped with a black transparent mirror. We need to focus the mirror face on the area indicated by the red arrow, as tracked by the sensor. When sunlight hits the mirror, it will pass through the black transparent mirror and emit diminished (weakened) rays. We can open the mirror at different angles depending on the requirement. 

That’s all for now. As you continue reading the research paper, you’ll understand that I have written about many methods. By studying them, you’ll get a clearer idea of which method is the most effective. Many of the methods I tested didn’t work — for example, the one using a sprinkler shower drone — because the water couldn’t diffuse properly. However, that method can still be used for agriculture, railway coach cleaning, and wildlife preservation. Among all these, I believe the satellite-based refraction method is the most effective. I feel confident that it will work. The rain-based method is also good, but it's only temporary — it only provides relief on the day it rains. Coding method of weather looping is also good. My code is safe and gives a quasi-static result Please read the full research paper to understand the complete scope of my work. You can see in page number 37 in National Geography