Preliminary Research and Documentation

Modules

The complete project comprises of the following modules:

Real time object tracking system developed on AI/ML platforms using high resolution cameras
Intruder alert system

Real time Object Tracking System

A real time object tracking system is designed to identify, tag and monitor people and objects and store their image information in a database. Software applications can process this data and create workflows that help in securing seapods, and tracking boats, yachts and even.

Boat Identification

High resolution cameras, installed at strategic points like beaches, buoys and seapods continuously scan and monitor the water surface for ships, boats and yachts. Underwater cameras are installed on buoys, seapod bases, or mounted on rocks to monitor underwater activity. Data and images from both sources are collated and a unique ID is generated for each boat that passes by these strategic locations. The unique ID along with the image code is stored in a database. Technologies like TensorFlow or YOLO (You Only Look Once) use AI and ML to analyze the ship and a log is created every time the ship or boat passes by.

Optionally, a unique display code, QR code or AR code is generated and assigned for each boat by legal authorities. These are displayed on the ship and can be scanned and identified by cameras and software from far away.

Figure 1 - Sample image to illustrate real time object tracking and tagging boats using AI.

When an unidentified boat approaches a sea pod, the software triggers an alarm and notifies the residents, security personnel and legal authorities.

Intruder Identification

Intruder identification and theft prevention comprises of the following modules:

Motion sensors
Facial recognition system
Alarm system

~~All~~Data 3and ~~systems~~images from all these sources are ~~linked~~collated and a unique ID is generated for each person. Technologies like OpenCV, TensorFlow or YOLO (You Only Look Once) use AI and ML to identify a person a log is created every time the ~~software~~person ~~console~~passes ~~that~~by ~~monitors~~the ~~resident~~camera.

~~and seapod safety.~~

Motion Sensors

Motion sensors or movement sensors are electronic devices that detect and measure movement. It uses ultrasonic sensor technology and emit sound waves to detect presence of objects. Motion sensors are installed in different areas of the seapod. When residents are away, these motion sensors scan the covered area for intruders. When motion is detected, the sensor triggers an alarm and sends a notification to the resident and local authorities.

Facial Recognition System

High resolution cameras, installed at strategic points inside and outside seapods, buoys and boats continuously scan and monitor the area for intruders. Underwater cameras are installed on buoys, seapod bases, or mounted on rocks to monitor intruders trying to gain underwater access to seapods.

Intruder identification software allows ~~the~~

owners

~~Images~~and residents to enter images and details of ~~seapod~~family ~~owners~~to enter names and ~~residents~~image ~~are~~capture ~~pre-entered~~of ~~in the software~~family and friends. This data is stored in the database. ~~Residents can add as many guests, friends and families~~

Data and images from both sources are collated and a unique ID is generated for each boat that passes by these strategic locations. The unique ID along with the image code is stored in a database. Technologies like TensorFlow or YOLO (You Only Look Once) use AI and ML to analyze the ship and a log is created every time the ship or boat passes by.

When this person enters into the water, the AI module monitors the person position, section of body that is in water. Depending on the section of body that is above water, the algorithm tags them with a safety indicator.

~~For example, the following indicators are displayed on the console:~~

~~GREEN - Person is on sand, or a hard surface, is stationary or moving~~

~~GREEN - More than 50% of the body is visible, and is stationary~~

~~GREEN - More than 50% of the body is visible and is moving~~

~~YELLOW - Between 10% and 40% of the body is visible and stationary~~

~~YELLOW - Between 10% and 4% of the body is visible and stationary~~

~~RED - Less than 10% of the person is not visible for more than 30 seconds.~~

Each of these sample indicators will change in real time depending on the swimmer's images that are visible to the high resolution cameras. A log is written to the system and the database is constantly updated.

If a swimmer does not surface for more than 30 seconds, the software sends a signal and deploys the the unmanned underwater vehicle (rescue bot). Alternatively, if the monitoring lifeguard sees a red indicator on a particular person, he or she can manually deploy the UUV for rescue.

Wrist Tag

A GPS or RFID wrist tag is to be worn by swimmers when going into water. The GPS or RFID unit gives the exact position of the person wearing it. The wrist tag also monitors the pulse or heartbeat of the swimmer and relays the same to the console. If there is an irregularity in the pulse, and the person is in water, the person is tagged as YELLOW or RED in the software console.

Figure 2 - ASample ~~sample RFID/GPS wrist tag that has a distress button~~image to ~~raise~~illustrate ~~alerts.~~facial recognition system for family and friends using OpenCV and AI.

~~The wrist tag also has a push button that can raise~~When an ~~alarm.~~intruder ~~When~~breaks ~~the software or the wrist tag alerts are received, an unmanned underwater vehicle is deployed to that position for rescue.~~

Unmanned Underwater Vehicle (Rescue Bot)

~~An unmanned underwater vehicle is used for rescuing drowning victims. Based on data received from the software console, or if triggered manually by a lifeguard, the UUV sets course~~in to the ~~exact position of~~seapod, the ~~victim~~cameras ~~based~~scan onthe ~~GPS~~intruders ~~co-ordinates.~~face and compares it against the entries in the database. If no match is found, it triggers an alarm and sends a notification to the owners, residents and local authories.

Figure 32 - ~~Illustration~~Sample ofimage ato ~~sample~~illustrate ~~unmanned~~facial ~~underwater~~recognition ~~vehicle with easy grip handles.~~

~~The UUV (rescue bot) has easy grip handles~~system for ~~drowning~~intruder ~~victims~~using ~~to grab,~~OpenCV and ~~secure themselves. The vehicle is fitted with search lights and cameras, so that the rescue can be monitored from the console.~~AI.

~~Alternately, a lifeguard can disable the automatic mode (UUV-mode) and remotely operate (ROV-mode) the rescue bot.~~

~~Note: Detailed specifications and information about the unmanned underwater vehicle is available~~ ~~here~~.