we are atlas twin
What would you do if you had a copy of yourself? A digital presentation, identical to you in every way, in an accurate digital rendering of your home, workplace, neighborhood, or city? Even better: What if the digital version of you—your digital twin—was impervious to injury, pain, or embarrassment? The mind boggles at the possibilities. Suffice it to say, you’d probably be able to make decisions for yourself with a lot more certainty of the outcome.
50+ Project
120+ Employees
12 Industry awards
10 office in the country
global awards
2024 Top Digital-Twin Initiative Award
2023 Top Xr Company Award
2023 Startup Top 100 List
2019 Awe Auggıe
Best Enterprise Solution Awards
What We Do
Digital Rail System
Digital City
Digital Traffic
Digital Solar Plant
Digital WindMill Power Plant
why atlas twin
Real-Time Data Integration
Digital twins continuously collect data from physical assets, keeping the virtual model updated in real-time. This is achieved through sensors and other data collection tools. Real-time data is essential for monitoring processes and making quick interventions.
Accuracy and Precision
A digital twin must accurately represent the physical asset. This requires precise modeling of the system’s mathematical, physical, and behavioral characteristics. Inaccurate or incomplete data can compromise the validity of simulations and analyses.
Prediction and Simulation Capability
Digital twins should be able to simulate and predict future events and scenarios. By testing different scenarios, the system’s performance can be optimized, and potential issues can be identified in advance.
Adaptability and Learning Capacity
Digital twins must have the ability to adapt to continuously changing conditions. Supported by machine learning and artificial intelligence algorithms, a digital twin can learn from past data and make more accurate predictions in the future.
Monitoring and Diagnostic Capacity
Digital twins enable continuous monitoring of physical assets, allowing for early detection of malfunctions or performance drops. This helps reduce maintenance costs and improve operational efficiency.
Interactive and User-Friendly Interface
A digital twin should have an interface that allows users to easily interact with the data. Visualization, data analytics tools, and user-friendly control mechanisms make decision-making easier and make the digital twin more accessible.
Our working process
A digital twin is a virtual replica of a physical object, system, or process that continuously updates in real-time using data to optimize performance and predict future outcomes. When creating a digital twin we use the following data.
1.
Geographic Information Systems (GIS) Data
Essential for mapping the geographical structure of the city. It includes 3D models of physical structures like buildings, roads, bridges, parks, and water bodies. These data ensure that the city’s basic infrastructure is accurately represented in the digital environment.
2.
Infrastructure Data
Includes the mapping of distribution networks for essential services such as water, electricity, gas, and telecommunications. It provides information about the operational status, maintenance needs, and capacities of these systems, which is critical for managing and optimizing infrastructure.
3.
Transportation Data
Covers dynamic data on traffic density, public transportation networks (buses, trains, metros), road capacities, pedestrian pathways, and bike lanes. These data help optimize traffic flow and improve public transportation.
4.
Demographic Data
Includes socioeconomic data on the city’s residents, such as age, gender, income levels, and education. This data assists in making more accurate and equitable decisions in urban planning and service distribution.
5.
Environmental Data
Involves data on environmental conditions such as air quality, temperature, humidity, wind direction, and water quality. It also includes data for assessing the city’s risks to natural disasters (earthquakes, floods, fires). These are crucial for sustainability and disaster management.
6.
Energy Consumption Data
Required to analyze energy consumption patterns within the city. Monitoring the energy usage of buildings, industries, and transportation systems allows for the development of more efficient energy management strategies.
7.
Sensor and IoT Data
Data collected from smart sensors and Internet of Things (IoT) devices within the city. For example, real-time data from smart street lights, traffic lights, weather stations, and waste containers continuously update the city’s digital twin.
