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Thursday, March 28, 2024

9 research/development projects on AI launched

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From applications in agriculture to the education sector, the Department of Science and Technology Philippine Council for Industry, Energy and Emerging Technology Research and Development launched on Thursday nine new projects on artificial intelligence research and development aimed at spurring growth in this emerging industry in the Philippines.

9 research/development projects on AI launched
In a virtual launch, DOST PCIEERD unveiled the AI projects to be undertaken by the DOST-Advanced Technology Science Institute, University of the Philippines Mindanao, De La Salle University, University of the Philippines-Los Baños, and Caraga State University.

In a virtual launch, DOST PCIEERD unveiled the AI projects to be undertaken by the DOST-Advanced Technology Science Institute, University of the Philippines Mindanao, De La Salle University, University of the Philippines-Los Baños, and Caraga State University.

“AI is one of our priority areas as it truly can boost the country and usher us to the fourth industrial revolution. As a powerful agent for good, AI can disrupt traditional processes and provide solutions and opportunities that Filipinos can maximize,” said DOST-PCIEERD Executive Director Dr. Enrico C. Parinigit.

Autonomous vehicles that help the society

The Autonomous Societally Inspired Mission Oriented Vehicles (ASIMOV) Program, composed of two component projects, will be implemented by DOST-ASTI and UPMin.

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It will take on the challenge of developing AI-enhanced, mission-driven robots working autonomously or with humans to help address the society’s needs. In its initial phase, it will focus on laying the groundwork by developing and innovating these key functional modules of intelligent mobile robots: sensing, actuation, control, navigation, and communications.

UPMin will handle the Harmonized Aerial Watch and Knowledge-based Survey (HAWKS) Project, the aerial component of the ASIMOV program and will primarily conduct R&D towards the development of core technologies necessary for autonomous drone deployment. Unmanned aerial vehicles (UAVs) will be developed for easy monitoring, object detection, and mapping, with minimal human control.

While DOST-ASTI's is the Robot for Optimized and Autonomous Mission-Enhancement Response (ROAMER) Project. It will develop prototypes of unmanned ground vehicles (UGV) that will help increase productivity of different industries in the country, especially agriculture. Techs under Project ROAMER are envisioned to monitor, survey, and map agricultural farms for better decision-making and management.

These robots will initially be tested in realistic emulated surroundings and eventually evaluated in actual environments. They will be used as learning platforms for building effective field-ready robots during the later phases of the ASIMOV Program.

AI for efficient processing of available big data

UPMin will also spearhead the Philippine Sky Artificial Intelligence Program (SkAI-Pinas). Its main research component is the Automated Labeling Machine – Large-Scale Initiative (ALaM-LSI), which will be conducted in partnership with the DOST-ASTI once again.

SkAI-Pinas aims to bridge the gap between the availability of massive remote sensing data in the country and address the lack of a sustainable technology-based framework that will facilitate their widespread processing systematically and effectively.

It is comprised of an AI knowledgebase, including experts, protocol, and an AI repository for models and labeled images to accelerate the workflows of remote   sensing applications and fill the gaps in past and present remote sensing projects.

Through the ALaM-LSI Project, AI-based techniques are planned to be utilized to enable the development and deployment of relevant applications and services for Filipinos.

Tremor sensors to monitor the structural health of infrastructures

DLSU intends to develop a low-cost, wireless structural health monitoring system with visualization through the Intelligent Structural Health Monitoring via Mesh of Tremor Sensors (meSHM) Project.

The system will be made up of less than 50 sensors, will utilize internet of things (IoT) technology and mesh networks, and can be installed in buildings, bridges, or metro rail systems. The system will be pilot tested in the cities of Biñan and Sta. Rosa, Laguna before large-scale deployment within cities in Metro Manila.

Once fully developed, the meSHM team will work on the commercialization of the system for it to be used by different infrastructure stakeholders such as real-property owners, the Department of Public Works and Highways (DPWH), local government units (LGUs), and city engineers.

This will pave the way for a more complete data collection and analysis, and lead to upgraded studies and more policies on disaster preparedness and prevention that involve vertical and horizontal structures in the different cities in the country.

Chatbot that monitors the health of students

Another project from DLSU is the Development of Multi-lingual Chatbot for Health Monitoring of Public-School Children Project. The team behind this will create a system that can interpret audio input and can converse with students using two major Philippine languages, Filipino and Bisaya.

To achieve this, they will develop speech and natural language processing models that can provide appropriate and intelligent responses in the form of questions or suggestions.

The information gathered by the healthcare chatbot will be extracted to update the health database of the students stored in the cloud. Health analytics and visualization of the collected data will also be provided for decision-making.

The pilot version of this chatbot will be deployed in public schools in partnership with the Department of Education (DepEd).

Towed camera system for marine litter monitoring

To help protect the environment and reduce marine pollution, UPMin will develop a simple, cost-effective technology to monitor and quantify the marine litter in shallow coastal areas.

The UPMin will base their technology on an existing towed optical camera array system for deep sea monitoring that has undergone sea trials. They will redesign and improve this by adding sensors and cameras to be efficiently used in shallow coastal water surveys.

It will also have a built-in image processing and deep learning or machine learning capability that can identify marine litter, compute and the map area covered by litter and build models for predicting marine litter future scenarios.

Automated software for faster spectroscopy analysis

UPLB’s goal is to develop an automated software that accepts values from a standard Impedance Spectrometer and uses a machine learning algorithm to identify electrical, mass, and temperature parameters by looking into the time series plot and plot library. This also involves properly fitting a spectrum with sufficient parameters that minimizes common errors in existing numerical fittings.

The developed algorithm will be tested and deployed at UPLB’s Institute of Mathematical and Physical Sciences Instrumentation Laboratory. The laboratory houses projects concerning materials development and testing.

The program will be integrated with a simple user interface that anyone can conveniently use. One does not need to be familiar with the specifics of the program, it can be treated like a black box. The user can just input the values or parameters that s/he intends using. The academe, particularly research, and industries involving electronics, semiconductors, food, medicine, and agriculture, are targeted to benefit from this project.

Intelligent system for traffic control and management

Using an IoT sensor network and deep learning, CarSU will design and develop an intelligent traffic control and management system. It will monitor traffic in a selected area by using various devices that can measure several physical traffic parameters like flow, density, volume, headway, waiting time, throughput, as well as pollution.

Furthermore, the base station will be established and equipped with intelligent behavior and direct policy search capabilities using reinforcement learning to automatically and efficiently manage traffic and to avoid congestion.

To make this possible, the CarSU team will design a road and vehicle traffic simulation with traffic lights based in Butuan City.

They will also develop and test a prototype of intelligent mobile traffic lights and will design web-based or mobile-based applications that enable easy access traffic conditions.

Paringit expressed optimism and confidence that these AI projects can prompt progress to the country.

“As a leader and partner in enabling innovations by harnessing emerging technologies, we recognize that these cutting-edge AI projects that will be implemented by government agencies and higher education institutions (HEIs) will be a huge leap for the Philippines as we deep dive into the AI industry and harness its full potential.  These projects are a testament of our shared goal of uplifting our nation by making innovation work for the Filipino people,” Paringit said. 

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