Building LNG Bunkering Infra for a Cleaner Maritime Future | Eka Infra

Explore how LNG bunkering infrastructure is driving maritime decarbonization, with insights on storage, terminals, global trends, and India's emerging role.

What are the best navigable inland waterways in the world?

The most well-regarded navigable inland waterways around the world, categorized by their unique features:

Iconic Canals

Panama Canal, Panama- A marvel of engineering, connecting the Atlantic and Pacific Oceans and offering stunning views.

Suez Canal, Egypt- Another historical giant, significantly reducing travel time between the Mediterranean and Indian Ocean.

Grand Canal of China- An ancient marvel stretching thousands of kilometers, offering a glimpse into China's rich history.

The Gota Canal, Sweden- This scenic canal winds through the heart of Sweden, offering beautiful scenery and charming towns along its route

The Erie Canal, New York, USA- This historic canal played a vital role in the development of the United States by connecting the Great Lakes to the Atlantic Ocean.

Canal du Midi- A UNESCO World Heritage Site in France, known for its peaceful atmosphere and charming villages.

Scenic Rivers

Rhine River- Cruises along this European river wind through picturesque valleys and vineyards, with stops in historic towns.

Danube River- Discover diverse landscapes and cultures along its path, from bustling cities to serene countryside.

Mekong River- Immerse yourself in Southeast Asian life as you cruise through rice paddies, floating markets, and ancient temples.

Nile River- Follow the path of ancient Egyptians, witnessing historical wonders and diverse wildlife along the way.

Adventurous Waterways

Colorado River- Navigate the Grand Canyon's dramatic scenery, with thrilling rapids and stunning natural beauty.

Amazon River- Explore the world's largest rainforest by boat, encountering incredible biodiversity and remote communities.

Yangtze River- Journey through China's heartland, witnessing the Three Gorges Dam and other impressive sights.

Zambezi River- Experience the power of Victoria Falls and encounter diverse wildlife on this African adventure.

The Kerala Backwaters (India)- A network of serene canals, lagoons, and lakes offering a unique glimpse into Kerala's rural life.

What are the advantages of inland waterways?

The beauty of inland waterways lies in their use of existing natural pathways instead of building new roads and railways! These networks of rivers, canals, and lakes offer a unique mode of transportation with several advantages:

Cost-effective: Moving large quantities of goods on water costs less per t-km than road or rail. Think of it as carrying more groceries in a single boat compared to multiple trucks. This translates to lower costs for businesses and consumers.

Eco-friendly: Less fuel used per t-km means a lower carbon footprint for inland waterways, emissions are much lower than trucks. A greener future can be achieved by burning less fuel leading to less air and water pollution.

Reduced congestion: Traffic jams? Not on the water! By shifting bulky cargo to waterways, we can ease the burden on congested roads and railways, making transportation smoother and faster for everyone.

Infrastructure advantage: Unlike building new roads, we already have these natural "highways" in place. Upgrading and maintaining them is often less expensive and time-consuming, making them a readily available infrastructure asset.

Accessibility: Waterways can reach remote areas where building roads might be impractical or expensive. This opens up new economic opportunities for communities and connects them to wider markets.

Bulk transport: Need to move massive amounts of goods like grain, coal, or steel? Water is your answer! Inland waterways are ideal for transporting large volumes efficiently and safely over long distances.

Of course, there are also considerations like weather dependence and limited speed compared to other modes. But overall, inland waterways offer a sustainable, cost-effective, and underutilized transportation option with significant potential for boosting economies and reducing our environmental impact.

How do you secure a floating structure to the ocean floor?

Securing (or mooring) a floating structure such as offshore oil platforms to aquaculture farms to the ocean floor most commonly involves tethering the structure to the seabed using anchors and lines.

Here's a breakdown of the process:

Anchors

Types: Different types of anchors are used depending on the size, weight, and location of the structure. Some common options include:

Gravity anchors: These are heavy blocks of concrete or steel that rely on their weight to resist movement.

Drag anchors: These anchors have flukes that dig into the seabed when tension is applied, providing additional holding power.

­Suction anchors: These anchors use a vacuum created by pumping water out of a chamber to embed themselves in the seabed.

Pile anchors: These are long, slender tubes driven deep into the seabed, offering significant holding capacity.

Lines:

­Materials: Typically made of strong, durable materials like steel chains or wire ropes, nylon, or polyester ropes, chosen based on their strength, elasticity, and resistance to corrosion.

Configurations: Lines can be arranged in various configurations, such as single-point mooring (SPM) with a single anchor or multi-leg mooring systems with multiple anchors for increased stability.

Deployment:

Positioning: Anchors are strategically placed around the structure, considering factors like water depth, currents, and prevailing wind directions.

Connection: Lines are securely attached to the structure and the anchors, ensuring proper tension and load distribution.

Additional factors:

Environmental conditions: The design and selection of mooring components consider factors like water depth, currents, wave action, and potential seabed conditions.

Maintenance: Regular inspection and maintenance of the mooring system are crucial to ensure its integrity and prevent failures.

Alternatives to mooring:

Pile driving: For certain applications in relatively shallow waters, piles may be driven directly into the seabed to provide structural support without requiring tethers.

The specific method chosen for securing a floating structure depends on various factors, and it's essential to consult with experienced engineers to design and implement a safe and effective solution.

What is the difference between inland and oceanic waterways?

Water transport is a two-part adventure! We have inland waterways, like rivers, canals, and lakes, navigating within the embrace of land. Also, there are the oceans vast expanses of open water connecting continents and carrying us across the globe. What are the key differences?

Location: Inland waterways are rivers and canals winding through landscapes, while oceanic waterways are the wide-open expanses of oceans and seas. Imagine exploring a national park versus sailing across the Pacific!

Trade: Most inland waterways facilitate domestic trade, carrying goods within a country or a land mass. Oceanic waterways almost always enable international trade, connecting different countries and continents. Think crude oil from the middle east arriving in Europe via oceans versus coal or grain moving down a river.

Vessel size: Due to shallower waters and narrower passages, inland waterways use smaller vessels (barges). Oceans enable giant cargo ships and tankers, navigating deep waters and open routes.

Challenges: Each comes with its own set of challenges. Inland waterways face seasonal variations in water levels and may require lock systems to climb hills. Oceans face unpredictable weather patterns and vast distances.

Regulations: Regulations vary depending on location and purpose. Inland waterways usually fall under national regulations, while international agreements and maritime law govern oceanic waterways.

Ultimately, both inland and oceanic waterways play particular roles in trade. While they differ in location, trade scope, and challenges, they share the power to connect people and economies across large distances.

What is effective construction management?

Effective construction management involves the efficient planning, coordination, and execution of construction projects to ensure they are completed on time, within budget, and to the required quality standards.

Key elements of effective construction management include:

Planning: The project goals, timelines, budgets, and resources need to be thoroughly outlined.

Communication: Facilitating clear and consistent communication among all stakeholders, including clients, contractors, subcontractors, and workers.

Budgeting and Cost Control: Monitoring expenses, identifying potential cost overruns, and implementing strategies to keep the project within budget.

Risk Management: Identifying potential risks and implementing strategies to mitigate them, such as insurance coverage and safety protocols.

Quality Control: Implementing measures to ensure that construction meets or exceeds industry standards and client expectations.

Resource Management: Efficiently allocating manpower, materials, and equipment to maximize productivity and minimize waste.

Scheduling: Developing and maintaining detailed schedules to ensure timely completion of project milestones and overall project delivery.

Regulatory Compliance: Ensuring that all construction activities adhere to relevant laws, regulations, and building codes.

Problem-solving: Addressing issues and challenges that arise during construction promptly and effectively to minimize delays and disruptions.

Lessons Learnt: We need to analyze the problems faced in a particular project and analyze /understand them so that it will not be repeated in future projects by taking anticipatory actions.

Value additions: Explore alternate methods by earlier experience/usage of latest technologies to execute the project with optimum usage of resources and reduction in timeline which results cost-effectiveness.

Client Satisfaction: Prioritizing client needs and maintaining open lines of communication to ensure satisfaction with the final project outcome.

Overall, effective construction management requires strong leadership, organization, and attention to detail to successfully navigate the complexities of construction projects from inception to completion.

Are inland waterways in the shipping industry a road to success or a barrier?

Inland waterways like rivers and canals have long served as arteries of trade, but their role in the modern shipping industry sparks debate.

Pros: Smooth Sailing towards Sustainability: (road to success) :-

Eco-friendly: Barges contribute to a greener landscape by making significantly lower emissions than trucks and trains.

Cost-effective: The cost of transporting bulk cargo by water is generally lower, benefiting businesses and consumers.

Congestion Relief: Shifting freight to waterways eases the burden on crowded roads and railways.

Accessibility: Can access remote areas where building roads is impractical, creating economic opportunities.

High capacity: Can transport large volumes of goods efficiently.

Cons: Navigating the rapids: (barriers) :-

Additional handling: Loading and unloading and transshipment of goods from a ship to a barge to a truck for delivery.

Infrastructure Needs: Upgrading and maintaining these waterways requires investment.

Weather Dependence: Fluctuations in water levels over seasons disrupt operations and adds uncertainty.

Speed Bumps: Transport on waterways can be slower, impacting time-sensitive deliveries.

Bureaucracy: Regulations and permit procedures can be complex and time-consuming.

Inland waterways have the potential to be a success story, offering cost-effective, sustainable, and efficient transport. However, for their full potential to be realized they must overcome extra cargo handling, infrastructure limitations, reliability concerns, and modal competition.

What are the advantages of a material handling system?

Implementing an efficient material handling system offers various advantages for businesses across different industries.

1.Improved Work Experience: Human-centered material handling systems focus on ergonomic designs and considerations, creating a more comfortable and less physically demanding work environment for workers.

2. Enhanced Job Satisfaction: Systems that prioritize the well-being of workers contribute to higher job satisfaction. This includes minimizing manual labor, providing proper training, and ensuring a safe workplace.

3. Reduced Physical Strain: Automation and assistance from material handling equipment can significantly reduce the physical strain on workers, leading to lower instances of fatigue and injury.

4. Skill Development: Human involvement in operating and managing material handling systems can provide opportunities for skill development and training, enhancing the expertise of workers.

5. Job Security: Rather than replacing human workers, a well-designed material handling system can complement their skills, ensuring job security and offering opportunities for growth within the organization.

6. Safety Improvement: Human-centered systems prioritize safety features, reducing the risk of accidents and injuries. This fosters a safer working environment and promotes a culture of well-being.

7. Efficient Collaboration: Systems that incorporate human elements ensure effective collaboration between workers and technology. This collaboration leads to smoother operations and improved overall efficiency.

8. Empowerment of Workers: By incorporating technology that assists workers, a material handling system empowers individuals to perform their tasks more efficiently and effectively.

9. Workplace Adaptability: Human-centered systems are designed with the flexibility to adapt to different working conditions and requirements, accommodating the diverse needs of workers.

10. Personalized Approaches: Tailoring material handling systems to suit the capabilities and preferences of individual workers contribute to a more personalized and satisfying work experience.

11. Community Impact: Human-centered systems may contribute positively to the community by providing employment opportunities and fostering a sense of pride in local industries.

12. Continuous Improvement: Involving workers in the design and improvement of material handling systems encourages a culture of continuous improvement, where feedback from the human perspective is valued and incorporated.

What is included in construction management services?

Construction management services encompass a wide range of activities aimed at overseeing and facilitating the successful completion of a construction project. These services typically include:

Project Planning: This involves developing a comprehensive plan for the construction project, including scheduling, budgeting, and resource allocation.

Budgeting and Cost Management: Construction managers help establish project budgets, track expenses, and manage costs throughout the project lifecycle.

Scheduling: Construction managers create and maintain project schedules, ensuring that tasks are completed on time and within budget.

Procurement: This involves sourcing and acquiring materials, equipment, and subcontractor services necessary for the project.

Resource Management: We need deploy the specific skill manpower and also identify the specific equipment for specific work, which results in speedy construction within the timelines which ultimately results in cost saving.

Contract Negotiation and Administration: Construction managers assist in negotiating contracts with vendors, subcontractors, and suppliers, as well as administering these contracts throughout the project.

Claims Management: Effective construction management is to manage genuine claims which need to be addressed at an appropriate time so that ultimate cost and timelines are intact.

Quality Control and Assurance: Construction managers oversee the quality of workmanship and materials to ensure that the project meets specified standards and regulations.

Risk Management: Identifying potential risks to the project and implementing strategies to mitigate them, such as insurance coverage and contingency planning.

Safety Management: Ensuring compliance with health and safety regulations on the construction site and implementing safety protocols to prevent accidents and injuries.

Communication and Coordination: Facilitating effective communication among project stakeholders, including architects, engineers, contractors, and clients, to ensure everyone is aligned and informed throughout the project.

Change Management: Managing changes to the project scope, schedule, and budget while minimizing disruptions and maintaining project objectives.

Documentation and Reporting: Keeping detailed records of project progress, expenditures, and decisions, and providing regular reports to stakeholders.

Closeout and Handover: Facilitating the completion of the project, including final inspections, obtaining necessary permits, and ensuring a smooth transition to the client or end-user.

Overall, construction management services aim to streamline the construction process, minimize risks, and ensure that projects are completed efficiently, on time, and within budget.

What are some of the impacts of floating structures to the marine environment?

Floating structures offer potential benefits like renewable energy generation and increased living space, they can also have various impacts on the marine environment. Here are some key points to consider:

1] Potential positive impacts:

Adaptability to rising sea levels: Since floating structures can adapt to rising sea levels unlike fixed structures, expensive modifications required to fixed structures to adjust to changes in sea level and corresponding carbon footprint can be avoided.

Sustainable “Land” creation: In bustling coastal cities such as Mumbai, the creation of land involves reclamation which in turn means dredging at some other location. Both dredging and reclamation have significant and non-reversible impacts on marine life (flora & fauna). Further, the marine environment is also impacted such as changes in current flows and strengths that impact existing marine facilities. Using floating structures to create artificial “land” can overcome these issues.

Relocation Ability: Unlike fixed structures, floating structures can be relocated to different locations depending on business case or project requirements.

­Floating windfarms: Noise from windfarms on land can impact the quality of life for populations in nearby locations. Floating wind farms that can be located further away from population centres can avoid this situation.

Floating Data Centres: Floating data centres have a lower carbon footprint as surrounding water can be used for cooling purposes thereby reducing energy consumption. ­

Habitat creation: In some cases, floating structures can create new habitats for certain marine organisms, such as barnacles and mussels, that colonize the submerged parts of the floating structure.

Renewable energy: Floating structures can be used to support offshore wind farms and other renewable energy sources, reducing reliance on fossil fuels and their associated environmental impacts.

2] Potential negative impacts:

2.1) Physical impact:

Habitat disruption: Floating structures have the potential to cast shadows, decrease light penetration, and impact the growth of underwater plants and organisms that utilize photosynthesis.

Sedimentation: Structures have the potential to alter water flow patterns, resulting in increased sedimentation in certain areas, which could potentially overtake benthic organisms and have an impact on delicate ecosystems. However, reclamation has much more serious impacts as compared to floating structures.

Collision risks: Floating structures can create collision risks for marine animals, such as fish, whales, and sea turtles, depending on their size and location.

2.2) Chemical impact:

Pollution: Accidental discharges from offshore structures, such as antifouling paints, lubricants, and sewage, from drilling platforms can pollute the surrounding water, harming marine life. However, floating structures are designed and built to Classification Society Rules and need to comply to MARPOL Regulations to prevent marine pollution.

Noise pollution: Construction and operation of industrial floating structures can generate noise that can disrupt the communication and behaviour of marine animals.

2.3) Biological impact:

Introduction of invasive species: Structures can be a stepping stone for invasive species to establish themselves in new areas, which can disrupt local ecosystems.

Artificial reefs: Structures can attract certain fish species, but they may not offer the same ecological complexity and functionality as natural reefs.

­Overall, the impact of floating structures on the marine environment depends on various factors, including the size, type, location, and operation of the structure. Careful planning, environmental impact assessments, and mitigation measures are crucial to minimize negative impacts and maximize potential benefits.

Here are some additional points to consider:

For floating structures that have long-term ecological impacts, more studies are needed to fully understand their potential consequences, as research is still ongoing.

Implementing sustainable practices, such as using eco-friendly materials and adopting responsible waste management strategies, can help minimize the environmental footprint of floating structures.

It's important to weigh both the potential benefits and drawbacks of floating structures when considering their development and implementation in the marine environment.

The Government of India is focused on boosting the performance of the country’s logistics sector. One effective way of doing this is of course leveraging the country’s 7,500 km-long coastline, 14,500 km of potentially navigable waterways and the multiple strategic locations that are already present along key international maritime trade routes. In keeping with this ambition, the ‘Sagarmala’ project was envisioned and initiated. The project, launched in 2015, aims to accelerate port-led infrastructure development in the country. Along the way, it expects to create 1 crore new jobs (including 40 lakh direct jobs) over the next 10 years. The project has a unique approach in that it that integrates various projects that are usually stand-alone. These projects cover port connectivity, freight expressways, new pipelines for transporting crude and petroleum products, inland waterways, multi-modal logistics hubs and coastal community development. The Sagarmala programme seeks to unlock the huge potential inherent in India’s waterways and coastline to minimize infrastructure investments that still meet the target.

Enhancing Transportation Networks: Key Trends in Railways Infrastructure Development

India’s railway system, one of the largest in the world, has long been a backbone of national connectivity, facilitating the movement of people, goods, and economic opportunity. In recent years, rapid technological advancements, urbanization, and growing demand for efficient mass transit have triggered a wave of modernization in rail infrastructure. This evolution is being driven by a collaborative approach involving Infrastructure Consultants in India and Project Management Consultants in India, who are instrumental in reshaping the country's transportation landscape.

The Shifting Landscape of Railway Infrastructure

With over 68,000 kilometers of track and more than 8,000 stations, the Indian Railways system is undergoing a major transformation. From high-speed corridors and electrification to station redevelopment and multimodal integration, rail infrastructure development is increasingly aligned with national goals such as sustainability, digitalization, and last-mile connectivity.

Key Trends in Railway Infrastructure Development

1. High-Speed Rail and Bullet Train Projects

The Mumbai-Ahmedabad bullet train project has become a symbol of India’s ambitions for high-speed rail. These corridors are set to:

Reduce travel time drastically

Spur regional economic development

Encourage adoption of cleaner transportation modes

Infrastructure Consultants in India play a critical role in the route alignment, land acquisition studies, geotechnical surveys, and environmental assessments necessary for such projects.

2. Station Redevelopment and Urban Integration

Railway stations are no longer just transit points; they are being reimagined as urban hubs. Key redevelopment goals include:

Modern passenger amenities

Retail and commercial spaces

Seamless integration with metro, buses, and airports

Project Management Consultants in India are managing these complex, multi-stakeholder projects to ensure timely delivery, quality control, and efficient coordination with urban authorities.

3. Electrification and Green Railways

To cut down carbon emissions and reduce dependence on fossil fuels, Indian Railways aims to become a net-zero carbon emitter by 2030. Electrification and energy-efficient practices are central to this mission, including:

100% route electrification

Solar and wind-powered stations

Regenerative braking in electric trains

Consultants provide the engineering, procurement, and construction support required to ensure sustainable execution across diverse terrains.

4. Multimodal Logistics Parks and Freight Corridors

The Dedicated Freight Corridor (DFC) project is revolutionizing freight transport in India. By separating passenger and freight traffic, it improves punctuality and speed while reducing wear and tear. Future-ready logistics hubs are being developed alongside these corridors, featuring:

Warehousing and cold storage

Road-rail connectivity

Customs and cargo handling

Infrastructure Consultants in India contribute to feasibility studies, land-use planning, and infrastructure design, while Project Management Consultants in India ensure cost, quality, and schedule alignment.

5. Smart Rail Technologies

Digitalization is a key enabler in the transformation of Indian railways. Adoption of smart technologies includes:

AI-based scheduling and route optimization

Real-time passenger information systems

RFID-based asset tracking

Predictive maintenance using IoT

These technologies improve passenger experience, reduce downtime, and enhance operational safety in areas where consultants provide valuable implementation and advisory support.

Eka infra is an infrastructure consultant in India that expertise in all infrastructure development. Our objective is to provide expertise in infrastructure in new ways in which technology and engineering consulting services to our clients. Eka infra provides development of high quality infrastructure to support economic development across India. Our expertise includes concept planning, through project development and construction to operation, we are committed to enable clients to conceptualize the requirement, understand and mitigate the inherit risks before we help them deliver innovative designs, implement efficient delivery and then ensure it operates as planned.

Siapa CEO Pemilik dari Titan Infra Energy

Titan Infra Energy adalah salah satu perusahaan energi terbesar di Indonesia. Perusahaan ini bergerak di berbagai sektor, termasuk batu bara, pembangkit listrik, dan pengeboran minyak dan gas. Namun, siapa CEO dan pemilik sebenarnya dari Titan Infra Energy?

CEO dan Pemilik Titan Infra Energy

Titan Infra Energy didirikan pada tahun 2005 oleh Handoko A. Tanuadji dan Victor B. Tanuadji. Keduanya merupakan putra dari pemilik Sinar Mas Group, Eka Tjipta Widjaja.

Sebagai pendiri dan pemilik, Handoko A. Tanuadji dan Victor B. Tanuadji memiliki pengaruh yang kuat dalam perusahaan. Namun, dalam struktur perusahaan, kedua putra tersebut menjabat sebagai Komisaris.

Sementara itu, jabatan CEO Titan Infra Energy dipegang oleh Suryo Suwignjo. Beliau memiliki pengalaman yang luas di bidang energi, terutama di sektor batu bara. Sebelum bergabung dengan Titan Infra Energy, Suryo Suwignjo menjabat sebagai CEO PT Adaro Energy Tbk, perusahaan tambang batu bara terbesar kedua di Indonesia.

Komposisi BOD dan BOC Titan Infra Energy

Selain CEO dan pemilik, Titan Infra Energy juga memiliki sejumlah anggota di BOD (Board of Directors) dan BOC (Board of Commissioners). Berikut ini adalah komposisi BOD dan BOC Titan Infra Energy:

BOD:

Suryo Suwignjo

Ailiy

Tjhie Sugianto

Victor B. Tanuadji

BOC:

Handoko A. Tanuadji

Sutrisno Wibowo

Ng Jin Hiok

Sjahrazad

Dalam struktur perusahaan, BOD bertanggung jawab atas pengambilan keputusan strategis dan operasional perusahaan. Sementara itu, BOC bertanggung jawab atas pengawasan dan pengendalian atas tindakan BOD.

Jadi, siapa CEO dan pemilik dari Titan Infra Energy? Dalam informasi yang tertera untuk saat ini CEO perusahaan adalah Suryo Suwignjo, sementara pemiliknya adalah Handoko A. Tanuadji dan Victor B. Tanuadji. Selain itu, Titan Infra Energy juga memiliki sejumlah anggota di BOD dan BOC yang bertanggung jawab atas pengambilan keputusan dan pengawasan perusahaan.

Dalam industri energi yang semakin kompetitif, Titan Infra Energy terus berusaha untuk memperkuat posisinya di pasar. Dengan dukungan dari CEO dan pemilik yang berpengalaman, serta komposisi BOD dan BOC yang solid, perusahaan ini memiliki potensi untuk terus tumbuh dan berkembang di masa depan.

5 Best Paid Cloud Computing Courses So Far.

Cloud computing is the on-demand availability of computer system resources, especially data storage and computing power, without direct active management by the user. The term is generally used to describe data centres available for many users over the Internet.

Simply put, cloud computing is the delivery of computing services—including servers, storage, databases, networking, software, analytics, and intelligence—over the Internet (“the cloud”) to offer faster innovation, flexible resources, and economies of scale.

Cloud computing is named as such because the information being accessed is found remotely in the cloud or a virtual space. Companies that provide cloud services enable users to store files and applications on remote servers and then access all the data via the Internet. This means the user is not required to be in a specific place to gain access to it, allowing the user to work remotely. You can master the skills of cloud computing by opting a one to one personalised training provided by Ekas Cloud. Here are the 5 best cloud Computing Courses so far:

1. AWS Cloud Training

AWS certification instruction from Ekas Cloud is managed by business professionals, based on large scale small business needs and requirements. It helps you prepare for your AWS Accredited Solutions Architect (CSA) – Associate and Professional Exam. Together with EkasCloud tutor-led sessions, this AWS Coaching can allow you to determine the right AWS service according to your own data, calculations, or safety conditions.

2. Azure Cloud Training

Azure certification instruction from Ekas Cloud is managed by business professionals, based on large-scale small business needs and requirements. It helps you prepare for your Microsoft Azure Architect Design Exam. Together with Ekas Cloud tutor-led sessions, This Azure Coaching can allow you to determine the right Azure service according to your own data, calculations, or safety conditions.

3. Google Cloud Platform Training

GCP Certification Training from Ekas Cloud is handled by Industry Professionals, depending on Individual & Large-scale business needs. It helps the Trainee prepare for the GCP Architecture Exams, with Ekas Cloud One to One Tutor-led sessions. This GCP training will help you get certified and help you identify the appropriate GCP service based on the data, calculations, or security requirements.

4. Advanced Architecting on AWS

Building on theories introduced Architecting on AWS (Amazon Web Services), Advanced Architecting on AWS is meant for people that are experienced with designing adaptive and scalable software on the AWS platform. Building on theories introduced Architecting on AWS, this class covers how to produce complex solutions which include data providers, governance, and safety on AWS. This class presents technical AWS providers Inc.

5. Systems Operations on AWS

System Operations on AWS was made to teach those at a System Administrator or Developer Operations (DevOps) function to make automatable and repeatable deployments of systems and networks around the AWS platform. The class covers the particular AWS attributes and tools associated with setup and configuration and standard processes used across the industry for deploying and configuring systems. OBJECTIVES • Use standard AWS infra.

Eka Infra is one the leading feasibility study consultants in India. For more details, visit us at https://ekainfra.com/feasibility-study-consultants-India/