PROTON ELIC M-4

PROTON ELIC RB-I M-4 PROFESSIONAL IT'S A MONSTER

M-4 Professional underground imaging device domestic and national world's latest technology digital sensor device all developed by our company Assuva defense industry engineers facilitated. Command screen, High solution, 64 PXS Digital Thermal sensor, Three-axis magnetic. Digital sensor, adjustable axes, Personal sensitivity settings robust and lightweight body easy portable box design.

LET'S GET TO KNOW THE DEVICE IN BRIEF:

The M-4 Device has a completely digital sensor. The device magnetic sensor consists of three axes (XYZ) axes automatically scans, on the other hand, the rear command screen of the device is used when visual touch is desired.

For example; one-way (Z) axis scanning or scanning can be done by adjusting different axes such as (X,Y). In this scanning device, the command signal intensity on the back side can be seen and there is a rising and falling signal OSCILLATOR. Metallic objects rise upwards and are represented by red color, this situation processes the fluent instant signal.

Dark blue acicular also descends downwards into formations such as voids or light blue voids (rooms, tunnels, passages) on a wide surface.

On the other hand, this scanning process and all of these operations can be viewed from the command screen without being connected to a PC. The processed data can be viewed while the PC is connected.

The thermal sensor has 64 PXS features and the digitally processed data visualization and definition are very high.

In this scanning format, the full screen 64 PXS behind the rear command of the device offers the opportunity to see each point live with high resolution on the screen at an equal height.

These scans can be seen clearly in 3D with a PC connection when requested. The values between the data received on the command screen and the PC may differ by (1.2) units. However, the ground difference of the scan will be much more normal than the values seen at night and in wet ground, snowy ground, bumpy ground, etc. thermal mode scan detection.

Moreover, both sensor sensitivities can be assigned to the desired level of increase or decrease on the device's own command screen. And in a very dirty area, for example; in areas with waste metals, a comfortable and smooth image can be obtained while scanning. And many more personalized.

AREAS OF USE:



1-) MUSEUM AND GEOARCHAEOLOGICAL RESEARCH GROUND PRELIMINARY WORKS

2-) ASTRONOMY INSTITUTE METEOROCIALISTS

3-) UNIVERSITIES SCHOOLS EARTH SCIENCE DEPARTMENTS

4-) UNDERWATER MATERIAL AND IMAGING

5-) INSTITUTIONS AND ORGANIZATIONS SUCH AS AFAD, UMKE, SEARCH AND RESCUE AND POST-EARTHQUAKE LIVE DETECTION

6-) HOBBY OR PROFESSIONAL TREASURY AND ARCHAEOLOGICAL RESEARCH

7-) MUNICIPALITY PIPE, LARGE WATER LEAK DETECTION, GROUND IDENTIFICATION BEFORE UNDERGROUND EXCAVATION AND LOST PIPE MANHOLE DETECTION

8-) INSTITUTIONS OR ORGANIZATIONS RESPONSIBLE FOR PROTECTING NATO PIPELINES (DETERMINATION OF ILLEGAL PIPELINES)

9-) UNDERWATER CORPS AND SUNKEN SHIP SEARCHES

AND IT IS SUITABLE FOR USE IN DETECTING EVERY imaginable ANOMALIES UNDERGROUND OR WATER.



TECHNICAL SPECIFICATIONS:

-RADAR:MICRO WAVE DOPPLER RADAR

-FREQUENCY: 433 MHz

-SCANNING FREQUENCY: MAX 5 GHz

-LASER:1pps

-DIGITAL SENSOR SCAN:64 PXS

-MAGNETIC SENSOR: 3-AXIS

-MAX DEPTH: 50 MT

-MAX SCAN RANGE:1000 MT

-WORKING TEMPERATURE: BETWEEN -20 DEGREES & +40 DEGREES

-GOOD USE RESULT:%95

-SOFTWARE PRESENTATION FORM: 3D&3D TRANSFER WITH 4D (DAT) CVS

-BATTERY DURATION: 20,000 MLamp 30&50 HOURS MAY VARY DUE TO WEATHER CONDITIONS

-WARRANTY PERIOD: 2 YEARS

SCOPE OF DELIVERY:

- CARRYING BAG BLACK COLOR G SHOK WATERPROOF

-BACKPACK MIL TEC

-DEVICE MAIN UNIT

-PROP SENSOR

-POWER CABLE

-POWER BANK

-CHARGING ADAPTER

-NECK STRAP APPARATUS

-USER MANUAL



Compatible Computer windows 10





OPTIONAL ACCESSORY:

-GPS ANTENNA

-CUSTOM PRODUCTION PRINCIPLES

-BOX TYPE AND SHAPE DIFFERENCES



DOCUMENTS HE HAS:

1-) NATO STOCK CODE-( NCAGE-TH763 )

2-) WORLD STANDARDS (CE) CERTIFICATE

3-) ISO 9001 QUALITY CERTIFICATE

4-) ISO 14001 QUALITY CERTIFICATE

5-) ISO 22000 QUALITY CERTIFICATE

6-) ISO 45001 QUALITY CERTIFICATE

7-) ISO 27001 QUALITY CERTIFICATE

8-) ISO 10002 QUALITY CERTIFICATE

9-) ISO 18001 QUALITY CERTIFICATE

10-) OHSAS 18001 QUALITY





FAST DEVICE RECOGNITION CAPABILITY TECHNICAL INFORMATION PURPOSE

THERMAL SENSOR-) IT IS A 4 ROW 16 COLUMNS 64 PXS THERMAL CAMERA. IT CAN SEE THERMAL DIFFERENCES IN THE ANGLE IT LOOKS AT WITH A RESOLUTION OF 64 PXS. ITS VIEWING ANGLE IS 60 DEGREES.

MAGNETIC SENSOR-) MAGNETIC SENSOR MEASURES DC MAGNETIC FIELD INTENSITY AT ITS LOCATION. HAVING 64 PIECES OF THEM ALLOWS FASTER DATA COLLECTION BY MEASURING MAGNETIC FIELD AT 64 DIFFERENT POINTS AT THE SAME TIME.

THE SYSTEM CAN OPERATE EITHER THERMAL OR MAGNETICALLY. AFTER DATA IS COLLECTED FROM ALL SENSORS, IT SENDS THE DATA TOGETHER WITH THE DIRECTION INFORMATION TO THE COMPUTER SOFTWARE VIA BLUETOOTH.

THE CAMERA, WHICH IS AT THE CENTER OF A SPHERECHILE IN A COMPUTER ENVIRONMENT, PAINTS THE INNER SURFACE OF THE SPHERECHI'S SHELL IN CORRESPONDING COLORS. AN IMAGE IS FORMED AS THE COLOR CORRESPONDENT OF THE THERMAL OR MAGNETIC FIELD INTENSITY IN THIS DIRECTION.

PROTON ELIC RB-I DEVICE DETECTS THE SEARCHED TARGET FROM A REMOTE THROUGH ITS (THERMAL AND MAGNETIC) SENSORS, IMMEDIATELY REFLECTS ITS DEPTH AND POSITION ON THE COMPUTER SCREEN TO THE OPERATOR, ON THE OTHER HAND IT PROVIDES DETAILED INFORMATION ABOUT WHAT THE TARGET IS AND ITS METAL TYPE. IN ADDITION TO THE DEVICE FAST DETECTION OF FORMS SUCH AS ROOM, TUNNEL, PASSAGE, SHELTER, BURIED AMMUNITION, VITAL MATERIAL, IT ALSO HAS THE POSSIBILITY OF DETECTING IF THERE IS AN ELEMENT HIDDEN BEHIND TREES OR UNDER SNOW THROUGH ITS THERMAL SENSORS. PRESENTS.

THIS DATA PRESENTATION IS VERY EASY TO USE AND UNDERSTAND DUE TO ITS 3D VISUAL SPECIAL SOFTWARE. THE USER CAN GET INSTANT DATA PRESENTATION WITH START STOP COMMANDS AND ALL COMMANDS AND SOFTWARE HAVE A TURKISH MENU.

IF REQUIRED, THIS DATA CAN BE IMMEDIATELY VIA THE MAP AND GETTING GPS RECORDINGS. THE SOFTWARE IS ADAPTED FOR THIS SITUATION.

THE DEVICE CAN BE USED ALONE BY ONE PERSON.

DESCRIPTION:

TECHNICAL FIELD: It is related to the operating system of a three-dimensional panoramic display device that can take 360-degree images and data recording, obtained by combining any desired sensor with an IMU sensor.

INFRASTRUCTURE OF MY SITE: Today, technology is developing and updated every day. Three-dimensional (3D) image formation is also one of the developing technologies. While it is easy to perceive the width and height ratios of an object with the eye, it is not possible to perceive the depth of the same object. Separate images are provided for the right and left eyes, and a three-dimensional image is formed by the combination of these two images in the brain. 3D photo or film cameras also function in a similar way and record using a recording technique. In other words, they capture the image from a separate lens and record it.

Nowadays, two cameras used for 3D film shooting focus on the same point by calculating the viewing angles and it is desired that the focused cameras are moving on the same path at the same time. It is possible to obtain three-dimensional images with cameras moving on different times and paths from each other. For this reason, the cameras are fixed in order to eliminate unwanted movements and differences.

DESCRIPTION

THREE-DIMENSIONAL PANORAMIC DISPLAY DEVICE AND OPERATION SYSTEM 5 Technical Field The invention is related to a three-dimensional panoramic display device and operation system that can record 360-degree images and data, obtained by combining any desired sensor with an IMU sensor. 10 Infrastructure of the Invention Today, technology is developing and updating every passing day. Three-dimensional (3D) image formation is also one of the developing technologies. While it is easy to perceive the width and height ratios of an object with the eye, it is not possible to perceive the depth of the same object. Separate images are provided for the right and left eyes, and a three-dimensional image is formed by combining these two images in the brain. 3D photo or film cameras function in a similar way and record using a recording technique. In other words, they capture the image from two separate lenses and record it. 20 Today, the two cameras used for 3D film shooting focus on the same point by calculating the viewing angles, and it is desired that the focusing cameras are recorded moving at the same time and on the same path. It is not possible to obtain three-dimensional images with cameras that move at different times and paths. For this reason, cameras are fixed to each other in order to eliminate unwanted movements and differences. One of the images that can be adapted to a three-dimensional model is the panorama. Panorama allows multiple images taken from different angles to be combined into a single wide-angle image. Panoramic cameras can obtain both 180-degree and 360-degree panoramic images using one or more 30 lenses. The sound and images obtained with the panoramic camera are recorded in the data recording medium. The image data measured or recorded by image processing can be transferred from one electronic medium to another electronic medium with the help of a computer and software and read on the device.

It is rendered. In the known state of the art, three 5-dimensional images can be obtained by combining two-dimensional (x and y axis) data and data from only one sensor can be recorded at the same time. In the current technique, data is collected and visualized by sampling method by keeping it fixed to the ground. Positioning is done either manually or by using positioning satellites such as GPS. The user obtains visual data by collecting 10 samples by visiting almost every point of the land where he/she will conduct research. Today, sensors that act as a bridge by connecting the physical environment and electronic devices vary according to the input sizes of the variables. The 15 values of these variables such as temperature, pressure, wavelength, current, concentration and permeability are measured by mechanical, thermal, electrical, magnetic, radiation and chemical sensors and converted into electrical signals. Sensors are grouped in two groups according to their feeding methods as passive sensors and active sensors. While passive sensors measure the signals they receive from their environment, active sensors produce their own signals and measure the interactions of this signal with the external environment 20 and require more energy since they emit their own signals. Active sensors provide analog or digital signal outputs depending on the type of signal they produce. Analog sensors are also converted to digital signals using (A/D) analog25 digital converters before the signal is directed to the microcontrollers. In digital sensors, there is no variability in the input and output values as in analog sensors and they produce discrete signals. The invention in question, a three-dimensional panoramic display device and operating system; sends the signal to the microcontroller with analog sensors or digital sensors as in the state of the art 30, but unlike the state of the art, it combines the information sent to the microcontroller with the IMU (Inertial Measurement Unit) 2 and can record 360-degree images and data in a three-dimensional panoramic manner. The invention communicates with the main unit 5 via USB, Bluetooth or Wifi thanks to this recording program made with the three-dimensional panoramic display device and operating system. The main unit sends the data coming from the sensors connected to it to the program with the 360-degree stance angle obtained from the IMU sensor. It reflects a viewing angle looking from the center of a sphere to the inner wall of the sphere on the screen. This program can be opened in a computer environment and with this record transferred to the computer environment, by looking from the inside of a sphere towards the inner shell of the sphere at 10 desired angles, the 360-degree anomaly differences of the shooting point can be examined panoramically. This perspective is calculated from the quaternion data coming from the IMU sensor. According to the stance angle obtained, the relevant area of the inner wall of the sphere is painted in the relevant color according to the intensity of the data coming from the sensor. Thus, the user holds the 15 sensors at different angles and ensures that the inner wall of the sphere is painted according to the signal level received from the sensor. After a certain scan, the visual equivalent of the signal intensity obtained with the program will start to be created on the inner wall of the sphere. The effect of visual shapes has been increased with various signal processing and interpolation algorithms. Thus, even at low signal levels, distinct images are obtained 20. The structural and characteristic features of the invention and all its advantages will be understood more clearly thanks to the figures given below and the detailed explanation written by making references to these figures, and therefore this evaluation should be made considering these figures and the detailed explanation. 25 Figures Helping to Explain the Invention Figure 1: Schematic representation of the operating system of the three-dimensional panoramic display device References Helping to Explain the Invention 30 1. Microcontroller 3 2. IMU sensor 3. Digital sensors 4. Analog sensors 5. Control buttons 5 6. LCD panel 7. Wireless module 8. Computer a. Transmitting the signal from the digital sensors to the microcontroller via the digital communication line 10 b. Transmitting the signal from the microcontroller to the computer via the wired communication line c. Transmitting the signal from the analog sensors to the microcontroller via the analog communication line d. The signal coming from the microcontroller is transmitted to 15 modules wirelessly via a wireless communication line. Description of the Invention The invention is a microcontroller (1), IMU sensor (2), digital sensors (3), analog sensors (4), control buttons (5), LCD panel (6) and

The invention relates to a three-dimensional panoramic display device and its operating system consisting of 20 wireless module (7) sections. The invention in question is composed of the following three-dimensional panoramic display device; microcontroller (1) that controls the entire system and combines the information it receives from the sensors with the IMU sensor (2), IMU sensor (2) that detects motion in three-dimensional space and directs it 360 degrees, digital sensors (3) that provide digital communication, analog sensors (4) that provide analog communication, control buttons (5) consisting of keypads that allow the user to control the device, LCD panel (6) that displays the menu and instantaneous data by allowing the device settings to be made, and wireless module (7) that provides wireless communication with the computer (8) sections integrated with each other. The process steps of the operating system of the three-dimensional panoramic display device, which is the subject of the invention, are as follows: 4 • Transmission of the signal coming from the digital sensors (3), which consist of acceleration, gyro and compass sensors in the IMU sensor and sensitive thermal and magnetic sensors operating as sensors and communicate with the microcontroller 5 in the control unit via the digital sensors I2C and SPI interfaces, to the microcontroller (1) via the digital communication line (a), • Transmission of the signal coming from the microcontroller (1) to the computer (8) via the wired communication line (b), • Transmission of the signal coming from the analog sensors (4), which consist of sensitive thermal and magnetic sensors and are read by the internal 10 16Bit ADC of the microcontroller, to the microcontroller (1) via the analog communication line (c), • Transmission of the signal coming from the microcontroller (1), which can communicate with the program wirelessly via USB or wirelessly via Bluetooth or Wifi, to the wireless module (7) via the wireless communication line (d). 15 The invention in question can also work with three-dimensional panoramic display device and operating system thermal and magnetic sensors. Thus, thermal detection of the image to be recorded is also provided. 20 The invention can record 360-degree images and data in three-dimensional panoramic display device and operating system by combining the information sent to the microcontroller (1) with the IMU sensor (2) and can also keep this record in its own memory. The recording with the three-dimensional panoramic display device and operating system can be opened in the computer (8) environment with the program. 25 With this record transferred to the computer (8), by looking at the inner shell of a sphere from the inside of the sphere at the desired angle, the 360-degree anomaly differences of the shooting point can be examined panoramically. Magnetic, electromagnetic, thermal or optical sensors can be used as measurement sensors in the device of the invention. The magnetic sensor is a sensor with a sensitivity of 30 1V/50uT working in the fluxgate technique coded TT-140. It gives the magnetic field intensity to the system as a voltage output in the range of 0-5V. 5 The invention in question receives the angle of stance from the IMU sensor with the main unit I2C protocol. It also receives the magnetic field strength value measured from the magnetic sensor with 16bit ADC. It combines these two data panoramically and sends the obtained data to the computer in real time via Bluetooth or any desired interface. 5 Three-dimensional panoramic display device and operating system, the computer program visualizes the data it receives in a way that the user can understand by coloring it according to the relevant angle of stance. The program visualizes the inside of a sphere's shell as a camera looking from the center of the sphere. The received angle of stance and magnetic field strength are painted according to the relevant angle and strength of the sphere's shell. The user paints the shell by taking measurements from 10 different angles as much as possible. Thus, over time, if a magnetic sensor is used, a magnetic projection is formed inside the sphere's shell, and if a thermal sensor is used, a thermal projection is formed. This invention will allow the user to collect data from that point in 3 axes and 360 degrees of stance angle without leaving the point he is at with this technique. This process can be likened to 3 15-axis cameras. These cameras have cameras looking at multiple different directions. The data obtained from these cameras without changing their angles are combined to obtain 360-degree viewing angles on all 3 axes. The sensor used searches for a 1-pixel color according to the angle of the position. The user rotates around and collects data, paints the sphere he is in 20 and obtains a 360-degree image on 3 axes. The technical and all other features mentioned in each request are followed by a reference number, and these reference numbers are only

The claims are used to facilitate understanding, therefore they should not be considered as limiting the scope of any of the process steps indicated by these reference numbers for exemplification purposes. It is clear that a person skilled in the art can also demonstrate the innovation set forth in the invention by using similar embodiments and/or apply this embodiment to other areas for similar purposes used in the relevant art. Therefore, it is also obvious that such embodiments will lack the criterion of innovation and especially exceeding the state of the art. 6 CLAIMS 1. The invention relates to a three-dimensional panoramic display device and operating system that outputs the magnetic field intensity to the system as a voltage output 5 in the range of 0-5V with a magnetic sensor with a sensitivity of 1V/50uT operating in the TT-140 coded fluxgate technique, and its feature is; It is characterized by the integration of the following sections: IMU sensor (2) which receives the magnetic field intensity value measured from the magnetic sensor with 16bit ADC and the stance angle with the main unit I2C protocol by controlling the entire system and the microcontroller (1) obtained by combining these two data panoramically, IMU sensor (2) which sends the data to the computer in real time via Bluetooth 10 or any desired interface, digital sensors (3) which provide digital communication, analog sensors (4) which provide analog communication, control buttons (5) consisting of keypads that allow the user to control the device, LCD panel (6) which shows the menu and instantly received data by allowing the device settings to be made and wireless module (7) which provides wireless communication with the computer (8) 15. 2. It is related to the three-dimensional panoramic display device and operating system according to Claim 1, and its feature is; The three-dimensional panoramic display device, which can connect both digital and analog sensors to the system, is characterized by the following process steps: • Transmission of the signal from the digital sensors (3) that consist of the acceleration, gyro and compass sensors in the IMU sensor and the sensitive thermal and magnetic sensors operating as sensors and that communicate with the 25 microcontrollers in the control unit via the I2C and SPI interfaces to the microcontroller (1) via the digital communication line (a), • Transmission of the signal from the microcontroller (1) to the computer (8) via the wired communication line (b), • Transmission of the signal from the analog sensors (4) that consist of sensitive thermal and magnetic sensors and are read by the 30 internal 16-Bit ADC of the microcontroller to the microcontroller (1) via the analog communication line (c), 7 • Transmission of the signal from the microcontroller (1) that can communicate wirelessly with the program via USB or wirelessly via Bluetooth or Wifi to the wireless module (7) via the wireless communication line





DEVICE FACILITIES AND CAPABILITIES

IT HAS THE ABILITY TO DETECT TUNNEL CAVE-LIKE FORMATIONS BURIED UNDERGROUND, MADE BY HANDICRAFT OR CARVED IN THE NATURAL GROUND (MADE BY CARVING REINFORCED CONCRETE-MASONRY WALLS-ROCK GROUND).



IT WORKS PERFECTLY IN ALL GROUND CONDITIONS (WET-SNOWFUL-ICY-ROCKY-RUGGED-MINERAL.) ETC.

IN ADDITION TO THESE OPPORTUNITIES, DEPTH AND DISTANCE DETECTION IS ALSO AVAILABLE IN THE DEVICE SOFTWARE.