DESC:FIELD OF THE INVENTION:

The present invention relates to an advance natural disaster sensing system and the method of sensing thereof. More particularly, the present invention relates to a system for sensing natural disaster by sensing the seismic waves arises inside the earth due to the movement of the tectonic plates and also a method of sending thereof.

BACKGROUND OF THE INVENTION:
Seismic wave is a wave of acoustic energy propagated within the Earth or along its surface. Seismic waves are caused by the sudden movement of materials within the Earth, such as slip along a fault during an earthquake. Volcanic eruptions, explosions, landslides, avalanches, and even rushing rivers can also cause seismic waves. The conventional method of measuring the seismic wave is using seismometer for advance detection of natural disasters related to seismic waves. Seismometer converts the vibration generated due to seismic waves into electrical signals, which can be displayed as seismograms on a computer screen to detect magnitude of vibrations. Due to the movement of the tectonic plates a series of seismic wave arises that travel through the interior or near the surface of the Earth. The first set of waves generated is P waves or primary waves, which is compressional or longitudinal waves. S waves, or secondary waves, come next since they travel more slowly than P waves. They travel in the same direction, but they shake the ground back and forth perpendicular to the direction the wave is traveling. Advance earthquake warning is possible by detecting the non-destructive primary waves that travel more quickly through the Earth’s crust than do the destructive secondary and surface waves.

There are few technologies in the world to detect seismic activity and most of them works on the principal of measuring vibrational energy of the wave generated during seismic activity. The instruments, such as seismograph or other instruments are used to detect earthquake by the measurement of vibration which can be converted into the electrical signal. Hence, the conventional method is not able to measure the magnitude of the electromagnetic waves generated by measuring electrical signal that arises due to generation of seismic waves. The related background of the art is also unable to give information about the distance, direction or magnitude at a same time and there is no such system available that can detect precursor seismic wave with its place of occurrence.

To sum up, the exiting technologies have many limitations that can be solved by the present invention. Hence, there is a requirement arises to provide a system that provides the technical solution to the above-mentioned problems. Therefore, the present invention discloses a system that addresses the issues related to earthquake or other disasters generated due to seismic activity and gives information about distance, direction and magnitude of seismic wave at a same time.

OBJECTIVES OF THE INVENTION:
The main object of the present invention is to provide a system for predetermining natural disasters, such as earthquake, arises due to seismic activity by detecting location, magnitude and direction of seismic waves.
Another objective of the present invention is to provide a system comprising multiple aluminum rods that helps to receive signals from seismic waves and carry the signal to the bio-organic filter.
Yet another objective of the present invention is to provide a system comprising bio organic filter which absorbs all the non-seismic waves and only transfer the seismic waves to the major system for detecting the distance, direction and magnitude of the seismic wave.
Another objective of the present invention is to use date or information obtained by the system of the present invention to locate the exact place and intensity of the seismic activity.
Yet another objective of the present invention is to provide equipment which can sense/ detect the precursor seismic waves arises inside the earth 30 minutes to 24 hours prior to the actual event.

SUMMARY OF THE INVENTION:
This summary is provided to introduce concepts related to a multi-functional cashew processing system and its structural features. The concepts are further described below in the detailed description. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter.

According to the present subject disclosure, there is provided an advanced natural disaster sensing system to detect and monitor electromagnetic wave parameters associated with natural disasters. The system comprises several key components that work together to provide real-time data on critical factors like magnitude, direction, and distance of electromagnetic waves, enabling accurate mapping and analysis of potential natural disasters.

The system of the present disclosure includes a system body, which houses essential structures such as a signal confirm stand, a magnitude confirm stand, and a distance-direction stand. These stands are strategically positioned to assist in verifying and mapping electromagnetic wave parameters, such as their magnitude, direction, and distance. The output data generated by these stands is indicative of the electromagnetic wave parameters and is displayed visually on a signal map, which is integrated into the system body. The signal map provides real-time visual indicators of the detected electromagnetic waves enhancing the ability of the natural disaster sensing system to monitor and respond to disaster conditions.

Further, a first power board is electrically connected to the earth through a first copper wire ensuring the system receives a stable electrical power supply. The power board distributes the electrical power to other components of the system. A second power board is connected to the first power board via a second copper wire forming an intermediary power distribution channel. Additionally, the earth is connected to the second power board via a third copper wire, featuring an on/off control to manage the power flow to the second power board. To maintain optimal operation, the system incorporates a bio-organic filter connected to the second power board through a fourth copper wire with an on/off control to regulate the continuous flow of electrical power. The bio-organic filter ensures that the power distributed to various components remains stable and clean, reducing any potential interference that could affect the sensing capabilities of the system.

Further enhancing the power distribution, the system includes a switched-mode power supply that is linked to the bio-organic filter through a fifth copper wire. This power supply is responsible for converting alternating current (AC) into direct current (DC), which is essential for the system’s components to function effectively. The switched-mode power supply is also connected to the second power board via a sixth copper wire, which, like other parts of the system, includes an on/off control to manage the conversion process. The signal map connected to both the system body and the second power board through a ninth copper wire and a tenth copper wire serves as the interface for visually indicating the detected electromagnetic wave parameters. The system's electromagnetic detection capabilities are critical for providing timely and accurate information about the proximity and severity of natural disaster events, enabling swift response actions. The advanced natural disaster sensing system integrates a range of components from power distribution boards and filters to electromagnetic wave mapping stands and signal visual indicators, all working cohesively to monitor and respond to natural disaster threats. By leveraging cutting-edge technology and meticulous power management. The system offers a reliable solution for tracking electromagnetic activity and contributing to disaster preparedness and mitigation.
In an aspect, the bio-organic filter configured to absorb noise or unwanted signals from the electrical power supply and to enhance the accuracy of electromagnetic wave detection and transfer the electromagnetic waves to the system body.
In an aspect, the signal confirm stand configured to provide a real-time indication of the presence of electromagnetic waves detected by the system body.
In an aspect, the magnitude confirm stand includes a calibration mechanism to ensure the accurate measurement of electromagnetic wave intensity.
In an aspect, the distance-direction stand configured to identify the precise source location of electromagnetic waves within a range of 0 to 300 Kilometers radius.
In an aspect, the switched-mode power supply configured with an overload protection mechanism to ensure the safety of downstream components.
In an aspect, the signal map is a digital display integrated with a graphical user interface (GUI) to visually indicate real-time electromagnetic wave parameters such as signal magnitude, direction, and distance.
In an aspect, the system body includes a processing unit configured to analyze electromagnetic waves data received from the signal confirm stand, magnitude confirm stand, and the distance-direction stand.
In an aspect, the on/off controls are integrated with a remote-control system for centralized operation and monitoring of the system components.
In an aspect, the copper wires are insulated with high-durability materials to ensure safe and efficient transmission of power and signals.
Various objects, features, aspects, and advantages of the inventive subject matter will become more apparent from the following detailed description of preferred embodiments, along with the accompanying drawing figures in which like numerals represent like components.

BRIEF DESCRIPTION OF THE DRAWINGS:
It is to be noted, however, that the appended drawings illustrate only typical embodiments of the present subject matter and are therefore not to be considered for limiting of its scope, for the invention may admit to other equally effective embodiments. The detailed description is described with reference to the accompanying figures. In the figures, a reference number identifies the figure in which the reference number first appears. The same numbers are used throughout the figures to reference like features and components. Some embodiments of system or methods or structure in accordance with embodiments of the present subject matter are now described, by way of example, and with reference to the accompanying figures, in which:

Figure 1 illustrates different parts of an advanced natural disaster sensing system, in accordance with the embodiment of the present invention.
Reference Numerals:
1. Earth
2. Power board 1
3. Power board 2
4. Bio organic filter
5. AC to DC SMPS
6. System body
7. Signal map
8. Signal confirm stand
9. Magnitude confirm stand
10. Distance direction stand
11. Copper wire earth to power board connect
12. Copper wire power board 1 to power board 2 connect
13. Copper wire power board 2 to bio organic filter connect
14. Copper wire bio organic filter to AC to DC, SMPS connect
15. Copper wire SMPS to system connector
16. Copper wire system to signal map connect
17. Copper wire earth to power board 2 connect on/off
18. Copper wire power board 2 to bio organic filter connect on/off
19. Copper wire power board 2 to SMPS connect on/off
20. Copper wire power board 2 to system connect on/off
21. Copper wire power board 2 to signal map connect on/off

Figure 2 illustrates a radial or polar representation of electromagnetic wave parameters, showing their direction, magnitude, and distance from a central origin point (epicenter).in an advanced natural disaster sensing system, in accordance with embodiment of the present invention.
Figure 3 illustrates six vertically positioned rods labeled as 1.1 to 1.6 indicating conductive elements for detecting or channeling electromagnetic waves in an advanced natural disaster sensing system to analyze specific parameters such as direction, magnitude, distance, in accordance with embodiment of the present invention.
Figure 4 illustrates power board 1 with at least 34 rectangular units arranged in rows, serving as connection points for grounding and power distribution for an advanced natural disaster sensing system, in accordance with embodiment of the present invention.
Figure 5 illustrates power board 2 with at least 38 rectangular units arranged in rows, serving as connection points for grounding and power distribution for an advanced natural disaster sensing system, in accordance with embodiment of the present invention
Figure 6 illustrates a bio-organic filter with a cylindrical structure containing multiple filtration layers for signal purification and pathways for signal flow for an advanced natural disaster sensing system, in accordance with embodiment of the present invention.
Figure 7 and 8 illustrates a signal confirm stand, a magnitude confirm stand, and distance-direction stand concentrically and interconnected to capture and process electromagnetic wave signals of an advanced natural disaster sensing system, in accordance with embodiment of the present invention.
Figure 9 and 10 illustrates distance-direction stand of an advanced natural disaster sensing system, in accordance with embodiment of the present invention.
Figure 11 illustrates a magnitude confirm stand for detecting and confirming the intensity of electromagnetic wave signals, aiding in precise parameter assessment for an advanced natural disaster sensing system, in accordance with embodiment of the present invention.
Figure 12 illustrates a signal confirm stand for detection and verification of incoming electromagnetic wave signals from the switched mode power supply (SMPS), ensuring accurate identification and validation of the signals received for an advanced natural disaster sensing system, in accordance with embodiment of the present invention.
The figure depicts the embodiment of the present invention for the purposes of illustration only. A person skilled in the art will easily recognize from the following description that alternative embodiments of the structures and methods illustrated herein may be employed without departing from the principles of the disclosure described herein.

DETAILED DESCRIPTION OF THE INVENTION:
The exemplary embodiments are provided to illustrate aspects of the invention, but the invention is not limited to any embodiment. The scope of the invention encompasses numerous alternatives, modifications and equivalents; it is limited only by the claims.

Numerous specific details are set forth in the following description in order to provide a thorough understanding of the invention. However, the invention may be practiced according to the claims without some or all of these specific details. For the purpose of clarity, technical material that is known in the technical fields related to the invention has not been described in detail so that the invention is not unnecessarily obscured. 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.

The present invention provides a natural disaster sensing system (100) which detects the precursor seismic waves arises within 30 minutes to 24 hours prior to seismic activity inside the Earth from the actual event.
An embodiment of the present invention is directed towards a system (100) to identify beforehand any earthquake wave and is beneficial in prevention of natural disasters associated to earthquakes.
In the embodiment of the present invention, the present invention discloses the antenna, wherein the antenna comprises of aluminium, copper rods, and the aluminium rods are placed along with copper rods that are dig inside the earth surface at 32 different directions in spherical manner, so that the required structure of the antenna is capable of receiving all the electromagnetic wave arises due to seismic activity. The main AC/ DC electrical power sources are connected to the aluminium and copper rods, and the rods are further connected to the 32 bio-organic filters (4) to transfer the electromagnetic signals. In a total 32 bio-organic filters (4) are used to receive signals from 32 different aluminium and copper rods individually. The bio organic filters (4) are further are connected to the major part of the system (100) which comprises signal receiver. The system (100) is further connected to alarm system wherein the alarm system is designed to map actual location of the epicenter of the earthquake.
In an embodiment of present invention, the advanced natural disaster sensing system (100) as shown in Figure 1. The system (100) of the present invention provides information about earthquake prediction, 30 minutes to 24 hours prior to the actual event.
Another embodiment of the present invention is directed towards a method of detecting earthquake or other seismic activity comprising the steps of:
1. All the precursor electromagnetic waves arises inside the earth during any seismic event has been received by the antenna comprising aluminum and copper rods of different length,
2. AC/DC current of different voltages has been supplied to the rods of the antenna to identify lower and higher frequencies of seismic activity,
3. The electromagnetic signals received by the aluminium rods are has been carried to the bioorganic filter through copper wire.
4. Bio-organic filter (4) absorbs all the non-seismic waves and only transfers the seismic waves to the major part of the system (100),
5. The received waves have been processed in the machine body (6) to give the information about distance, direction and magnitude of seismic wave.
6. An alarm system along with the region wise map has been connected to the main system part to precisely locate the epicenter, magnitude and direction of the seismic event.
The invention of the present invention addresses the issues related to earthquake and the invention thus is different in regards that it pre determines the earthquake or other disaster arises due to seismic activity based on the concept of bio organic filter rather than vibration based technology.
In one embodiment, as depicted in Fig. 1, the advanced natural disaster sensing system (100) comprises a system body (6) which includes several key components for detecting and analyzing electromagnetic wave parameters. Specifically, the system body (6) houses a signal confirm stand (8), a magnitude confirm stand (9), and a distance-direction stand (10) all of which assist in verifying and mapping electromagnetic wave parameters such as magnitude, direction, and distance. The data generated by these stands is then used to create a visual output on the signal map (7) which is integral to the system's operation.
Power distribution within the system begins with a first power board (2) which is electrically connected to the earth (1) via a first copper wire (11). This connection ensures the system receives a stable electrical power supply, which is then distributed to other components. A second power board (3) is connected to the first power board (2) through a second copper wire (12). Additionally, the earth (1) is further connected to the second power board (3) via a third copper wire (17), which includes an on/off control to regulate the power flow, enabling the second power board to function as an intermediate power distributor.
Power management continues with a bio-organic filter (4), which is connected to the second power board (3) via a fourth copper wire (13). The bio-organic filter (4) ensures a continuous flow of electrical power, and its operation is also controlled by an on/off switch (18), which regulates the power from the second power board to the filter. A switched-mode power supply (5) is connected to the bio-organic filter (4) via a fifth copper wire (14) and further linked to the second power board (3) through a sixth copper wire (19). The switched-mode power supply converts alternating current (AC) to direct current (DC) to power the system's components, and like other components, it also includes an on/off control to manage the conversion process.
Finally, the signal map (7) is connected to the system body (6) via a ninth copper wire (16) and is also linked to the second power board (3) through a tenth copper wire (21), both connections being governed by on/off controls. The signal map (7) provides a visual representation of the electromagnetic wave parameters detected by the system (100), displaying real-time data regarding their magnitude, direction, and distance. This connection ensures the system continuously monitors and visually indicates the detected electromagnetic activity, aiding in the early detection and response to potential natural disasters.
The system (100) integrates these components, power distribution boards (2, 3), bio-organic filters (4), switched-mode power supply (SMPS) (5), and electromagnetic wave detection stands (8, 9, and 10) to work in concert. The electromagnetic wave parameters are mapped and visually represented on the signal map (7), enabling effective monitoring and response to natural disaster threats.
Figure 2 illustrates a radial or polar representation used in the advanced natural disaster sensing system (100) to visually display electromagnetic wave parameters. The central origin point, or epicenter, serves as the reference for mapping the waves' direction, magnitude, and distance. The radial lines extend outward from the epicenter, each representing the direction of the detected electromagnetic waves. The length of these lines indicates the magnitude of the waves, with longer lines corresponding to stronger waves. The distance that the waves have traveled from the epicenter is also depicted by the radial lines, with farther lines representing waves that have propagated over greater distances. This mapping allows the system (100) to show the spread and intensity of the disaster in real time, offering critical data for assessing the affected areas and the potential impact. By integrating this data into the signal map (7), the system (100) provides a visual indication of the electromagnetic wave parameters, helping disaster response teams quickly understand the magnitude, direction, and reach of the waves, thereby enabling informed decision-making for effective disaster management.
The grounding of the rods from 1 to 32 on Earth (1) as follows:
1. N - North (System Epicenter To 3 Feet Distance), 0 To 50 Km Work, 1 Feet Height/10mm Thickness;
2. NBE -North By East (System Epicenter To 7 Feet Distance), 200 To 250 Km Work, 3 Feet Height/10mm Thickness;
3. NNE - North-Northeast (System Epicenter To 8 Feet Distance), 250 To 300 Km Work 3.5 Feet Height/10mm Thickness;
4. NEBN - Northeast By North (System Epicenter To 4 Feet Distance), 50 To 100 Km Work 1.5 Feet Height/10mm Thickness;
5. NE - Northeast (System Epicenter To 5 Feet Distance), 100 To 150 Km Work 2 Feet Height/10mm Thickness;
6. NEBE - Northeast By East (System Epicenter To 7 Feet Distance), 200 To 250 Km Work, 3 Feet Height/10mm Thickness;
7. ENE - East-Northeast (System Epicenter To 3 Feet Distance), 0 To 50 Km Work , 1 Feet Height/10mm Thickness;
8. EBN - East By North (System Epicenter To 4 Feet Distance), 50 To 100 Km Work 1.5 Feet Height/10mm Thickness;
9. E - East (System Epicenter To 8 Feet Distance), 250 To 300 Km Work 3.5 Feet Height/10mm Thickness;
10. EBS - East By South (System Epicenter To 6 Feet Distance), 150 To 200 Km Work 2.5 Feet Height/10mm Thickness;
11. ESE - East-Southeast (System Epicenter To 8 Feet Distance), 250 To 300 Km Work 3.5 Feet Height/10mm Thickness;
12. SEBE - Southeast By East (System Epicenter To 7 Feet Distance), 200 To 250 Km Work, 3 Feet Height/10mm Thickness;
13. SE - Southeast (System Epicenter To 5 Feet Distance), 100 To 150 Km Work 2 Feet Height/10mm Thickness;
14. SEBS - Southeast By South (System Epicenter To 7 Feet Distance), 200 To 250 Km Work, 3 Feet Height/10mm Thickness;
15. SSE - South-Southeast (System Epicenter To 8 Feet Distance), 250 To 300 Km Work 3.5 Feet Height/10mm Thickness;
16. SBE - South By East (System Epicenter To 3 Feet Distance), 0 To 50 Km Work, 1 Feet Height/10mm Thickness;
17. S - South (System Epicenter To 7 Feet Distance), 200 To 250 Km Work, 3 Feet Height/10mm Thickness;
18. SBW - South By West (System Epicenter To 4 Feet Distance), 50 To 100 Km Work 1.5 Feet Height/10mm Thickness;
19. SSW - South-Southwest (System Epicenter To 8 Feet Distance), 250 To 300 Km Work 3.5 Feet Height/10mm Thickness;
20. SWBS - Southwest By South (System Epicenter To 6 Feet Distance),150 To 200 Km Work 2.5 Feet Height/10mm Thickness;
21. SW - Southwest (System Epicenter To 7 Feet Distance), 200 To 250 Km Work , 3 Feet Height/10mm Thickness;
22. SWBW -Southwest By West (System Epicenter To 5 Feet Distance), 100 To 150 Km Work 2 Feet Height/10mm Thickness;
23. WSW - West-Southwest (System Epicenter To 8 Feet Distance), 250 To 300 Km Work 3.5 Feet Height/10mm Thickness;
24. WBS - West By South (System Epicenter To 7 Feet Distance), 200 To 250 Km Work, 3 Feet Height/10mm Thickness;
25. W - West (System Epicenter To 8 Feet Distance), 250 To 300 Km Work 3.5 Feet Height/10mm Thickness;
26. WBN - West By North (System Epicenter To 3 Feet Distance), 0 To 50 Km Work , 1 Feet Height/10mm Thickness;
27. WNW - West-Northwest (System Epicenter To 4 Feet Distance), 50 To 100 Km Work 1.5 Feet Height/10mm Thickness;
28. NWBW - Northwest By West (System Epicenter To 6 Feet Distance), 150 To 200 Km Work 2.5 Feet Height/10mm Thickness;
29. NW - Northwest (System Epicenter To 5 Feet Distance), 100 To 150 Km Work 2 Feet Height/10mm Thickness;
30. NWBN - Northwest By North (System Epicenter To 7 Feet Distance), 200 To 250 Km Work, 3 Feet Height/10mm Thickness;
31. NNW - North-Northwest (System Epicenter To 8 Feet Distance), 250 To 300 Km Work 3.5 Feet Height/10mm Thickness;
32. NBW -North By West (System Epicenter To 6 Feet Distance), 150 To 200 Km Work 2.5 Feet Height/10mm Thickness.
Figure 3 illustrates six vertically positioned rods, labeled as 1.1 to 1.6, which represent conductive elements in the advanced natural disaster sensing system (100). These rods 1.1 to 1.6 intended to detect electromagnetic waves and analyze specific parameters such as direction, magnitude, and distance. Each of the rods 1.1 to 1.6 functions as a sensor to capture electromagnetic waves, with their placement allowing for accurate measurements of wave parameters in a three-dimensional space.
The rods 1.1 to 1.6 works as conductive elements and strategically positioned to create a detection grid that can evaluate the direction of incoming electromagnetic waves relative to the position system (100). By comparing the signals detected by each rod, the system (100) determine the direction from which the electromagnetic waves are emanating. The magnitude of the electromagnetic waves is assessed by measuring the intensity of the signal received by the rods, with stronger signals leading to higher readings of magnitude. The placement of the rods (101 to 1.6) helps ensure that the system (100) can capture waves coming from various angles, providing a comprehensive understanding of wave intensity from all directions.
Additionally, the distance of the electromagnetic waves from the system (100) determined by analysing the time delay or the strength of the signals detected by the rods. The configuration of the six rods (1.1 to 1.6) allows the system (100) to triangulate the source of the electromagnetic waves and estimate the distance from the epicentre or the origin of the natural disaster event. By using these vertically positioned conductive elements (1.1 to 1.6), the system is able to effectively analyse and map the electromagnetic waves parameters, helping to assess the severity location, and potential impact of a natural disaster.
The connection of the Rods labeled as 1.1 to 1.6 of the system (100) with power board 1 (2) and power board 2 (3) as follows:
1. N - North Earth To Power Board2/Power Board3
2. NBE -North By East Earth To Power Board2/Power Board3
3. NNE - North-Northeast Earth To Power Board2/Power Board3
4. NEBN - Northeast By North Earth To Power Board2/Power Board3
5. NE - Northeast Earth To Power Board2/Power Board3
6. NEBE - Northeast By East Earth To Power Board2/Power Board3
7. ENE - East-Northeast Earth To Power Board2/Power Board3
8. EBN - East By North Earth To Power Board2/Power Board3
9. E - East Earth To Power Board2/Power Board3
10. EBS - East By South Earth To Power Board2/Power Board3
11. ESE - East-Southeast Earth To Power Board2/Power Board3
12. SEBE - Southeast By East Earth To Power Board2/Power Board3
13. SE - Southeast Earth To Power Board2/Power Board3
14. SEBS - southeast by south earth to power board2/power board3
15. SSE - South-Southeast Earth To Power Board2/Power Board3
16. SBE - South By East Earth To Power Board2/Power Board3
17. S - South Earth To Power Board2/Power Board3
18. SBW - South By West Earth To Power Board2/Power Board3
19. SSW - South-Southwest Earth To Power Board2/Power Board3
20. SWBS - Southwest By South Earth To Power Board2/Power Board3
21. SW - Southwest Earth To Power Board2/Power Board3
22. SWBW -Southwest By West Earth To Power Board2/Power Board3
23. WSW - West-Southwest Earth To Power Board2/Power Board3
24. WBS - West By South Earth To Power Board2/Power Board3
25. W - West Earth To Power Board2/Power Board3
26. WBN - West By North Earth To Power Board2/Power Board3
27. WNW - West-Northwest Earth To Power Board2/Power Board3
28. NWBW - Northwest By West Earth To Power Board2/Power Board3
29. NW - Northwest Earth To Power Board2/Power Board3
30. NWBN - Northwest By North Earth To Power Board2/Power Board3
31. NNW - North-Northwest Earth To Power Board2/Power Board3
32. NBW -North By West Earth To Power Board2/Power Board3
Figure 4 and Figure 5 illustrate two power boards i.e. Power Board 1 (2) and Power Board 2 (3) configured to serve as essential components for grounding and power distribution in the advanced natural disaster sensing system (100).
Power Board 1 (2) illustrates along with 34 rectangular units arranged in rows, serving as connection points for the grounding and power distribution within the system (100). These rectangular units are strategically placed across the power board 1(2), ensuring that each unit can facilitate the proper routing of electrical power and connection to various components of the system (100). The rows of units are likely organized in a structured manner to optimize the distribution of power to different parts of the system (100), ensuring efficient and reliable performance. These units (1-34) also play a key role in grounding provides a safe path for electrical current and preventing potential damage to components due to electrical surges or faults. The arrangement of 34 units ensures that Power Board 1 (2) equipped to handle the distribution of electrical power while maintaining safety and stability throughout the system (100).
Further, the Power Board 2 (3) comprises 38 rectangular units arranged in rows, similar to Power Board 1, but with a slightly higher number of units for expanded power distribution capacity. This power board 2 (3) serves a similar function in the system (100) providing grounding and power distribution to the Rods (1 to 32) as discussed in Figure 2 & 3. The additional units on Power Board 2 (3) indicate a greater requirement for power handling or the need to support more complex elements within the system (100). Each of the 38 units provides a designated point for connection, ensuring the electrical power is appropriately routed and distributed to the necessary components, while maintaining grounding to safeguard against electrical issues. The row arrangement of these units on Power Board 2 (3) also optimized for efficient power flow ensuring that the system (100) operates effectively while preventing overloads or power failures. Together, both Power Board 1 (2) and Power Board 2 (3) are critical for managing the electrical power supply in the advanced natural disaster sensing system (100). The arrangement of the rectangular units (1-38) allows for organized and efficient power distribution while ensuring the safety and grounding of the system (100), which is crucial for reliable operation, especially during the high-demand scenarios that may occur during natural disasters. These power boards provide the necessary infrastructure for the system (100) to detect and process electromagnetic wave parameters for to its overall functionality and performance.
Figure 6 depicts, the bio-organic filter (4) in the advanced natural disaster sensing system (100) is a crucial component configured to enhance the accuracy of signal detection by selectively filtering out non-seismic electromagnetic waves. The bio-organic filter (4) comprises of multiple layers of bio-organic materials, including a mixture of natural extracts and substances, which work together to absorb unwanted signals while allowing seismic waves to pass through. The bio-organic filter is housed in a 20 mL test tube, with ingredients such as 2 mL of neem leaf extract, 5 mL of karanj leaf extract, 1 gram of salt, 1 gram of chowk, 1 mL of lemon strip extract, 1 mL of Madar's milk, 1 mL of mango strip extract, 2 mL of mustard oil, and 1 mL of milk from the peepal tree. Additionally, two copper springs are incorporated into the filter (4), which may contribute to the purification process. The bio-organic filter (4) is finely tuned to target specific wave frequencies associated with seismic activity, ensuring that only relevant seismic data is transmitted for further analysis. By eliminating interference from other electromagnetic sources, such as electrical noise or radio frequencies, the filter improves the reliability of the system (100). This enables the system (100) to detect and analyze seismic waves, which are critical for monitoring natural disaster events like earthquakes. In this way, the bio-organic filter (4) plays a vital role in ensuring the system (100) accurately identifies and processes the electromagnetic waves essential for disaster monitoring, leading to more informed decision-making during emergency response efforts.
Figures 7 and 8 illustrate the configuration of three critical components in the advanced natural disaster sensing system (100). The natural disaster sensing system (100) comprises a signal confirm stand (8), a magnitude confirm stand (9), and a distance-direction stand (10). These stands (8, 9, and 10) are arranged concentrically and interconnected to capture and process electromagnetic wave signals effectively, providing accurate data for the detection of natural disasters.
The signal confirm stand (8) is positioned at the center of the arrangement forming the core unit responsible for confirming the presence of electromagnetic waves. It continuously detects the electromagnetic signals emanating from a potential natural disaster, such as seismic waves from an earthquake or signals from a volcanic eruption. These stands ensures that the system (100) actively monitoring the surrounding environment, verifying that the electromagnetic waves exist and are captured for further analysis. The signal confirms stand (8) integral to the real-time detection of waves and provides feedback to the system for on-going monitoring.
The magnitude confirm stand (9) confirms the magnitude, which is tasked with measuring the intensity/magnitude of the electromagnetic waves detected. The magnitude confirm stand (9) evaluates the strength of the signals, providing crucial data on the severity of the disaster event. The magnitude confirm stand (9) sensitive to the amplitude of the electromagnetic waves, and its readings help in understanding the power or intensity of the waves. This data is vital for assessing the potential impact of the disaster, such as the magnitude of an earthquake or the intensity of a volcanic eruption. The magnitude confirm stand (9) works in conjunction with the signal confirm stand (8), but its focus is on quantifying the strength of the detected signals.
Further, the distance-direction stand (10) positioned outward from the magnitude confirm stand (9), forming the outermost layer of this concentric setup. Its purpose is to determine the direction from which the electromagnetic waves are emanating and the distance they have travelled. The distance-direction stand (10) essential for pinpointing the location of the source of the disaster, whether it's an earthquake's epicenter or the location of volcanic activity. By analysing the direction and distance of the waves, the distance-direction stand (10) contributes to the spatial mapping of the disaster’s origin. It provides valuable geographical data that helps in assessing the spread and potential impact area of the disaster, allowing for more effective response strategies. These three stands (8, 9, and 10) are interconnected in a concentric arrangement, allowing them to work in harmony to capture and process electromagnetic wave signals in a coordinated manner. The signal confirm stand (8) ensures the detection of the waves, the magnitude confirm stand (9) measures their intensity, and the distance-direction stand (10) identifies their origin and propagation. Together, signal confirm stand (8), the magnitude confirm stand (9), and the distance-direction stand (10) enable the advanced natural disaster sensing system to provide a comprehensive understanding of the disaster's nature, magnitude, and location, facilitating prompt and informed decision-making for emergency response.
Figures 9 and 10 illustrate the distance-direction stand (10) of the advanced natural disaster sensing system (100) showcasing its component and functionality in detecting and analysing the direction and distance of electromagnetic waves. The distance-direction stand (10) positioned to interact with the other components of the system (100) specifically the signal confirm stand (8) and the magnitude confirm stand (9) to provide critical information about the source of the detected waves. The primary function of the distance-direction stand (10) is to identify the direction from which the electromagnetic waves are originating, as well as the distance they have travelled. This is essential for determining the geographical location of the natural disaster, such as the epicentre of an earthquake or the point of eruption of a volcanic activity. The stand is equipped with specialized sensors or components that can detect the angle of arrival of the electromagnetic waves, helping to triangulate the location of the disaster source. In addition to direction, the distance-direction stand (10) also measures the distance the waves have travelled from their source or epicentre. Overall, the distance-direction stand (10) is a vital component that helps pinpoint the disaster's source location and provides data on the propagation of electromagnetic waves. This data in combination with the information from the signal confirm stand (8) and magnitude confirm stand (9) enables the advanced natural disaster sensing system (100) to offer a comprehensive analysis of the disaster's nature, location, and potential impact, thereby supporting timely and informed emergency response actions.
Figure 11 illustrates the magnitude confirm stand (9) of the advanced natural disaster sensing system (100) is a crucial component intended to detect and confirm the intensity of electromagnetic wave signals. The magnitude confirm stand (9) plays a vital role in assessing the strength/magnitude of the detected electromagnetic waves, which is essential for understanding the severity of a natural disaster event, such as an earthquake or volcanic eruption. By measuring the amplitude of the waves, the magnitude confirm stand (9) provides accurate data on the intensity of the signal, which is key to determining the disaster’s potential impact. This information helps in evaluating the scale of the event and supports decision-making for disaster response. The magnitude confirm stand (9) works in conjunction with other components of the system including the signal confirm stand (8) and distance-direction stand (10) to deliver a comprehensive analysis of the electromagnetic waves. Through its precise detection and confirmation of wave intensity, the magnitude confirm stand (9) contributes significantly to the overall functionality of the advanced natural disaster sensing system (100) and ensures accurate and reliable disaster monitoring.
Figure 12 illustrates the signal confirm stand (8) of the advanced natural disaster sensing system (100), which plays a crucial role in detecting and verifying the incoming electromagnetic wave signals. The signal confirm stand (8) is intended to work in tandem with the switched-mode power supply (SMPS) to ensure accurate identification and validation of the electromagnetic signals received by the system. The signal confirm stand (8) continuously monitors the incoming signals confirming their presence and quality, and ensuring they are electromagnetic waves relevant to the disaster event being detected, such as those generated by seismic activity. By verifying the integrity of the signals, the signal confirm stand helps eliminate potential noise or interference from external sources, ensuring that only valid signals are processed further by the system. This process is vital for the overall reliability of the advanced natural disaster sensing system (100) as it ensures that subsequent analysis, such as magnitude and direction determination based on accurate and verified data. In essence, the signal confirm stand (8) acts as the initial checkpoint in the signal processing chain, providing confidence in the accuracy and relevance of the data received from the SMPS for disaster monitoring.
As will be readily apparent to those skilled in the art, the present embodiment may quickly be produced in other specific form characteristics. Therefore, the present embodiments are to be considered merely illustrative and not restrictive, the scope of the invention being indicated by the claims rather than the preceding description, and all changes which come within therefore intended to be embraced therein. ,CLAIMS:We Claim:

1. An advance natural disaster sensing system (100) comprising:
a. a system body (6) comprises;
i. a signal confirm stand (8):
ii. a magnitude confirm stand (9);
iii. a distance-direction stand (10);
b. a first power board (2) electrically connected to an earth (1) via a first copper wire (11) to receive and distribute electrical power supply;
c. a second power board (3) ) connected to the first power board (2) via a second copper wire (12) and the earth (1) further connected via a third copper wire (17) with an on/off control to works the second power board (3) as an intermediate power distributor;
d. a bio-organic filter (4) connected to the second power board (3) via a fourth copper wire (13) with an on/off control (18) to continuously flow the electrical power from the second power board (3) to the bio-organic filter (4);
e. a switched mode power supply (5) configured to connect the bio-organic filter (4) through a fifth copper wire (14) and the switched mode power supply (5) further connected to the second power board (3) via a sixth copper wire (19) with an on/off control to covert the AC power to DC power; and
f. a signal map (7) connected to the system body (6) via a ninth copper wire (16) and further connected to the second power board (3) ) via a tenth copper wire (21) with an on/off control to visually indicates the detected electromagnetic waves parameters;
wherein the signal confirm stand (8), the magnitude confirm stand (9), and the distance direction stand (10) each configured to assist in verifying, mapping of the electromagnetic waves parameters and generates output indicative data of electromagnetic waves parameters such as magnitude, direction, and distance using the signal map (7).

2. The advanced natural disaster sensing system (100) as claimed in claim 1, wherein the bio-organic filter (4) configured to absorb noise or unwanted signals from the electrical power supply and to enhance the accuracy of electromagnetic wave detection and transfer the electromagnetic waves to the system body (6).

3. The advanced natural disaster sensing system (100) as claimed in claim 1, wherein the signal confirm stand (8) configured to provide a real-time indication of the presence of electromagnetic waves detected by the system body (6).

4. The advanced natural disaster sensing system (100) as claimed in claim 1, wherein the magnitude confirm stand (9) includes a calibration mechanism to ensure the accurate measurement of electromagnetic wave intensity.

5. The advanced natural disaster sensing system (100) as claimed in claim 1, wherein the distance-direction stand (10) configured to identify the precise source location of electromagnetic waves within a range of 0 to 300 Kilometers radius.

6. The advanced natural disaster sensing system (100) as claimed in claim 1, wherein the switched-mode power supply (5) configured with an overload protection mechanism to ensure the safety of downstream components.

7. The advanced natural disaster sensing system (100) as claimed in claim 1, wherein the signal map (7) is a digital display integrated with a graphical user interface (GUI) to visually indicate real-time electromagnetic wave parameters such as signal magnitude, direction, and distance.

8. The advanced natural disaster sensing system (100) as claimed in claim 1, wherein the system body (6) includes a processing unit configured to analyze electromagnetic waves data received from the signal confirm stand (8), magnitude confirm stand (9), and the distance-direction stand (10).

9. The advanced natural disaster sensing system (100) as claimed in claim 1, wherein the on/off controls (17, 18, 19, 21) are integrated with a remote-control system for centralized operation and monitoring of the system components.

10. The advanced natural disaster sensing system (100) as claimed in claim 1, wherein the copper wires (11, 12, 13, 14, 16, 17, 19, 21) are insulated with high-durability materials to ensure safe and efficient transmission of power and signals.