(January 2025 - Present)

Photogrammetry App for 3D Reconstruction | Swift · Xcode · RealityKit · Apple Vision Framework · LiDAR

• Developed a macOS app using Apple’s RealityKit Photogrammetry to convert image sets into textured 3D meshes.

• Integrated LiDAR depth capture, image preprocessing, and export to USDZ/OBJ, enabling seamless use in AR/BIM workflows.

• Supported construction-scale scanning for site capture and asset modeling, streamlining design coordination.

LiDAR-Powered Construction Safety Device (In Progress)

• Co-developing a real-time safety device using LiDAR and object detection to identify proximity hazards and unsafe conditions.

• Engineered edge-based detection for PPE compliance, fall-risk behavior, and spatial zone violations.

• Designed alert logic to trigger real-time feedback on-site, targeting improved response time and incident reduction.

Automated Safety Inspection + Compliance Dashboard | Google Apps Script · Google Forms/Docs · JavaScript · Drive API

• Built a fully automated safety inspection system converting form responses into logged, timestamped PDF reports.

• Integrated with Google Drive folders for auto-sorting by project, inspection type, and severity rating.

• Achieved 90% reduction in manual report time, while enhancing transparency and audit-readiness for safety teams.

Google Sheets-Based Dynamic Schedule Automation | Google Sheets · Apps Script · Field Data Integration

• Designed and deployed real-time construction schedules using field input triggers and dynamic spreadsheet logic.

• Improved cross-team responsiveness and coordination by 40%, enabling proactive task management and delay mitigation.

• Integrated daily safety logs and toolbox talk records directly into schedule dashboards for operational-safety alignment.

Safety Certificates & T&M Ticket Logger | Apps Script · Google Sheets/Drive · Email API

• Developed a logging system to track training certificates, auto-rename files, flag expiry dates, and send automated alerts.

• Created a T&M (Time & Material) ticket tracker for labor/equipment hours with photo evidence, client approval logs, and daily summaries.

• Improved compliance tracking and accelerated back charge documentation by 75%, improving dispute resolution and field-office coordination.

Concrete QC Pre-Pour Checklist Automation | Google Forms/Docs · Apps Script · Conditional Logic

• Digitized pre-pour checklist with conditional workflows for form validation, photo requirements, and approval routing.

• Synced with project schedule to flag missing documentation prior to pours, reducing QC hold points and rework risk.

• Boosted field adoption by making the system mobile-friendly and organizing training sessions.

Data Projection & Growth Forecasting Tool | Google Sheets · Query Functions · Forecast Models

• Developed forecasting models to predict project pay application amounts, based on past productivity and data.

• Visualized trends across labor output, equipment usage, and material cycles to inform cash flow and resource planning.

• Integrated safety scores and quality metrics into a growth readiness dashboard, highlighting crew strengths and risk flags.

Safety Management Automation Tools | Google Apps Script · Google Sheets/Docs · Drive API

• Built digital site-specific safety binder maker that uses Google Sheets/Docs and Drive API to create log files, make data logging easy, and generate ready-to-send safety binder PDFs.

• Resulted in a 70% reduction in administrative burden and significantly improved data integrity across field safety documentation.

Project Showcase: Prefabricated and Modular Structure Technology (August 2023 - December 2023)

• Technology Integration:

During this project period, I conducted a comprehensive Maturity Assessment and Cost-Benefit Analysis to explore advancements in Prefabricated and Modular Construction Technology. Here is an overview of key accomplishments:

• Maturity Assessment and Cost-Benefit Analysis:

Conducted an in-depth evaluation of the current state of prefabricated and modular construction technology, assessing its maturity level and analyzing the potential cost savings and benefits associated with its implementation. Our findings provided valuable insights into the feasibility and strategic advantages of adopting these innovative construction methods.

• Identification of High-Potential Use Cases:

Utilizing our expertise in construction technology, identified high-potential use cases where prefabricated and modular construction methods could be effectively utilized. This involved highlighting technological advancements in the field and performing a SWOT analysis to derive strategic insights, guiding our approach toward maximizing the benefits of these innovative techniques.

• Project Presentation and Technology Showcase:

To showcase findings and technological advancements, prepared a comprehensive project presentation, which included a detailed analysis of our research findings, case studies, and strategic recommendations. The presentation was accompanied by a video demonstration, providing visual insights into the capabilities of prefabricated and modular construction technology. You can watch project presentation (https://www.youtube.com/watch?v=NNykawyiEcs).

• Virtual and Collaborative Environments:

In addition to technology integration, we explored the potential of virtual and collaborative environments to enhance project communication and decision-making processes:

• 360 Virtual Tours: We implemented 360 Virtual Tours using Holobuilders, providing stakeholders with immersive project experiences. These tours allowed stakeholders to explore construction sites virtually, gaining a comprehensive understanding of project progress and design elements. You can experience our 360 Virtual Tour (https://app.holobuilder.com/app/?p=b8ee96db-ca99-45bd-b786-c7feda4fc888&s=1698260274225).

• Interactive Spaces: We created immersive and interactive spaces utilizing Mozilla Hubs, fostering collaborative virtual environments for efficient communication and decision-making among project stakeholders. These interactive spaces facilitated real-time discussions, design reviews, and decision-making processes, enhancing project coordination and efficiency.

• In our pursuit of optimizing project communication and decision-making, we harnessed the power of Building Information Modeling (BIM), Point Cloud technology, and Navisworks for clash detection and extensive data analysis. This integration allowed us to create immersive virtual and collaborative environments that facilitated efficient project coordination and management:

• BIM Integration: Leveraging BIM technology, developed detailed digital representations of construction projects, encompassing architectural, structural, and MEP elements. These BIM models served as comprehensive repositories of project information, enabling stakeholders to visualize, analyze, and interact with the project's virtual counterpart in unprecedented detail.

• Point Cloud Integration: By incorporating Point Cloud data captured through advanced scanning technologies like LiDAR, we enriched our virtual environments with precise 3D representations of existing physical spaces. Point Cloud data provided high-fidelity scans of construction sites, capturing intricate details and dimensions with unparalleled accuracy. Integrating Point Cloud data into our virtual environments enhanced realism and authenticity, allowing stakeholders to explore and navigate construction sites virtually with utmost precision.

• Navisworks for Clash Detection: Navisworks, a powerful software tool for construction project coordination, played a pivotal role in our virtual and collaborative environments. Using Navisworks, we conducted clash detection analyses to identify and resolve conflicts between building systems and components, such as clashes between structural elements and MEP systems. Navisworks facilitated clash detection by overlaying BIM models and Point Cloud data, enabling stakeholders to visualize clashes in 3D and streamline coordination efforts.

• Key Points:

1. Enhanced Visualization: Integrating BIM, Point Cloud, and Navisworks enabled stakeholders to visualize construction projects with unparalleled realism and detail. Virtual environments accurately mirrored real-world conditions, providing stakeholders with immersive experiences resembling physical site visits.

2. Precise Clash Detection: Navisworks facilitated precise clash detection by analyzing BIM models and Point Cloud data for conflicts between building systems and components. Stakeholders could identify clashes, discrepancies, and spatial constraints in virtual environments, enabling proactive resolution and minimizing costly rework during construction.

3. Collaborative Workflows: Integrated BIM, Point Cloud, and Navisworks technologies fostered collaborative workflows, enabling seamless communication and collaboration among multidisciplinary teams. Stakeholders could access and interact with project information in real time, facilitating collaborative design reviews, coordination meetings, and project updates.

• In summary, integrating BIM, Point Cloud, and Navisworks technologies revolutionized virtual and collaborative environments, setting new standards for project communication, visualization, and decision-making in the construction industry. By harnessing the power of advanced technologies and data-driven insights, we transformed project delivery, driving efficiency, innovation, and excellence in every aspect of construction. 

• Skills: Building Information Modeling (BIM) | Point Cloud Integration | Navisworks Clash Detection | Virtual Environment Creation | Data Analysis | Project Coordination | Construction Management | Technical Integration | 3D Visualization | Communication and Collaboration | Revit Modeling | Holobuilders Implementation |  Mozilla Hubs Development | SWOT Analysis | Cost-Benefit Analysis | Project Controls | Risk Management | Technology Assessment | Maturity Assessment | 360 Virtual Tours

Public Works Organization of New York City (January 2023 - May 2023)

• Research and Expertise in Public Infrastructure:

During this period, I delved into the intricate workings of the Public Works Organization of New York City, undertaking comprehensive research and acquiring valuable expertise in various aspects of public infrastructure management. 

Dedicated significant time and effort to studying the organizational structure, operational procedures, and strategic objectives of NYC's Public Works Organization. This involved analyzing official documents, studying historical data, to understand how the organization functions comprehensively.

• Insights into Budgeting Processes:

One of the focal points of my research was NYC's budgeting processes for public infrastructure projects. I explored the intricacies of budget allocation, expenditure tracking, and financial planning within the city's vast and diverse infrastructure network. This gave me valuable insights into the financial constraints and opportunities associated with public works projects in a dynamic urban environment.

• Expertise in Safety and Risk Management:

Given the unique challenges of construction projects in New York City, particularly regarding safety regulations and risk mitigation, I immersed myself in studying safety protocols, risk management strategies, and regulatory compliance requirements. This involved familiarizing with local laws, industry standards, and best practices for ensuring the safety of workers and the public while executing public infrastructure projects.

• Understanding Bonds and Insurance:

Another area of focus was gaining expertise in the intricacies of bonds and insurance related to construction projects. I studied the various types of bonds required for public works contracts, such as performance and payment bonds. I learned about the role of insurance in providing coverage for potential liabilities and risks associated with construction activities.

• Implementation of Project Controls:

Drawing on my research findings and acquired knowledge, I actively participated in implementing project controls for public infrastructure projects in New York City. This included developing and refining scheduling protocols, conducting cost estimates, and implementing risk management strategies to ensure the successful execution of projects within budget and on schedule.

Overall, my experience with the Public Works Organization of New York City gave me invaluable insights into the complexities of managing public infrastructure projects in a dynamic urban environment, further enhancing my civil engineering and project management expertise.

• Skills: Research | Budgeting | Financial Planning | Safety Management | Risk Mitigation | Regulatory Compliance | Project Controls | Scheduling | Cost Estimation | Public Infrastructure Management | Organizational Analysis | Data Analysis | Strategic Planning | Contract Management | Insurance Management

West MEC SWC Phase 3B, McCarthy (August 2022 - December 2022)

• Bid Tab Preparation and Quantification:

During my tenure on the West MEC SWC Phase 3B project with McCarthy, I played a pivotal role in bid preparation and quantification processes. 

• Bid Tab Preparation:

Meticulously prepared bid tabs. This involved carefully reviewing the project scope, architectural drawings, technical specifications, and subcontractor proposals to compile comprehensive bid documents. By ensuring accuracy and clarity in the bid tabs, I contributed to the competitive bidding process and facilitated informed decision-making.

• Quantification of Building Components:

As part of the bid preparation process, I quantified various building components essential for the West MEC SWC Phase 3B project. This included detailed quantification of doors, frames, hardware, tiles, painting materials, roofing supplies, flooring materials, framing elements, and drywall requirements. My ability to accurately quantify these components enabled me to develop precise cost estimates and effectively plan for material procurement and construction activities.

• Subcontractor Coordination and Cost Clarification:

In addition to bid preparation and quantification, I actively liaised with subcontractors to clarify scope inclusions, exclusions, and costs associated with various project items. By communicating clearly and transparently with subcontractors, I helped ensure alignment between project requirements and subcontractor proposals, thereby minimizing the risk of discrepancies or misunderstandings during the construction phase.

• Overall, my contributions to the bid preparation, quantification, and subcontractor coordination processes were instrumental in supporting efforts to successfully bid for the West MEC SWC Phase 3B project and lay the groundwork for its successful execution.

• Skills: Bid Tab Preparation | Quantification of Building Components | Construction Cost Estimation | Subcontractor Coordination | Attention to Detail | Technical Document Review | Project Scope Analysis | Clear Communication | Construction Management | Procurement Planning

Retrofitting Assessment of Engineering Center A (August 2022 - December 2022)

• Energy-Efficient Retrofit Construction:

During this project, I focused on researching and analyzing energy-efficient retrofit construction strategies to enhance Engineering Center A's sustainability and performance. Here are the key contributions:

• Thorough Research and Analysis:

I extensively researched energy-efficient retrofit construction methods, focusing on building envelope design, air conditioning (AC) efficiency improvements, and upgrading lighting systems. This involved studying industry best practices, analyzing case studies, and evaluating the latest technological advancements in retrofitting.

• Skilled Assessments Across Multiple Areas:

Utilizing my expertise in civil engineering and sustainable construction practices, I conducted skilled assessments covering various aspects of retrofitting, including building envelope, lighting, mechanical systems, interior layout, and structural integrity. These assessments were tailored to address Engineering Center A's unique challenges and requirements, considering its historical significance and high-rise structure.

• Comprehensive Retrofitting Options:

Based on the assessments' findings, I developed comprehensive retrofitting options that prioritized energy efficiency, cost-effectiveness, and sustainability. These options encompassed a range of solutions, from simple upgrades to advanced technologies, aimed at optimizing the building's performance while minimizing environmental impact.

• Tailored Plans for Client Needs:

Recognizing that each client has specific goals and constraints, I crafted retrofitting plans tailored to Engineering Center A's stakeholders' unique needs. Whether the focus was on cost-effectiveness, luxury upgrades, or sustainability initiatives, I ensured that the proposed solutions aligned with the client's objectives and budgetary considerations.

Overall, my involvement in this project enabled me to deepen my understanding of energy-efficient retrofit construction techniques and apply this knowledge to develop practical solutions for enhancing the performance and sustainability of Engineering Center A.

• Skills: Energy-Efficient Retrofit Construction | Research and Analysis | Assessment and Evaluation | Problem-Solving | Client-Centric Approach | Technical Proficiency | Communication | Project Management

Prefabricated Modular Structure for Affordable Housing (October 2021)

Aimed to develop a Prefabricated Modular Structure explicitly tailored for affordable housing. Leveraging cutting-edge software such as Revit, AutoCAD, Civil 3D, Fusion 360, and STAADPro, our team embarked on a mission to upgrade traditional construction methods and pave the way for accessible housing options for all.

• Project Overview:

The project's primary objective was to design and construct a modular housing solution that would meet the specific needs of low- to moderate-income individuals and families. By leveraging prefabrication techniques and standardized components, we aimed to streamline the construction process, reduce costs, and accelerate project timelines while maintaining high-quality standards.

• Design Excellence:

Using Revit, we created detailed 3D models of each modular component, allowing us to visualize the entire structure and identify potential design optimizations. AutoCAD was instrumental in creating precise 2D drawings and technical plans, ensuring the accurate fabrication and assembly of the modular units. Civil 3D played a crucial role in site planning, facilitating the integration of the modular structure within the existing urban landscape while adhering to regulatory requirements.

• Advanced Structural Analysis:

With STAADPro, we conducted comprehensive structural analyses to validate the performance and durability of our modular structure under various environmental and load conditions. This rigorous testing process enabled us to identify potential weaknesses and refine our design to ensure compliance with safety regulations and industry standards.

• Engineering Precision:

Precision engineering was at the core of our project, with careful attention paid to every aspect of the design and construction process. From material selection to assembly techniques, we employed best practices to achieve optimal results and ensure the long-term structural integrity of the modular housing units.

• Sustainability Integration:

We optimized the energy efficiency of our design, integrating sustainable practices into our construction process. This included using eco-friendly materials and energy-efficient systems to minimize the carbon footprint of our housing units, aligning with our commitment to environmentally conscious construction practices.

• Software Utilization:

1. Revit: Employed to create detailed 3D models of the prefabricated modular structure, allowing for accurate visualization and coordination among team members.

2. AutoCAD: Utilized for drafting and detailing architectural and structural components of the project, ensuring precision in design documentation.

3. Civil 3D: This technology is applied to civil engineering tasks such as grading, drainage design, and alignment optimization, enhancing the project's integration with site conditions.

4. Fusion 360: Used for collaborative design and simulation, facilitating seamless integration between design and manufacturing processes.

5. STAAD.Pro: This person was employed for structural analysis and design, ensuring that the prefabricated modular structure met safety and performance standards.

• Impact of Technology:

1. Enhanced Collaboration: These software tools enabled multidisciplinary teams to collaborate effectively, leading to integrated design solutions.

2. Efficiency in Design: Technology streamlined the design process, allowing for rapid iteration and optimizing the prefabricated modular structure.

3. Improved Accuracy: Advanced modeling and simulation capabilities ensured the design was based on precise engineering calculations, minimizing errors and rework.

4. Cost Savings: Technology contributed to cost savings by optimizing material usage and construction processes, making the project more economically viable.

5. Future Potential: Emerging technologies such as Building Information Modeling (BIM), Virtual Reality (VR), and Augmented Reality (AR) hold promise for further enhancing design visualization, construction planning, and stakeholder engagement.

• Affordable Housing Impact:

The Prefabricated Modular Structure presented a scalable and cost-effective solution for affordable housing projects. By reducing construction time and material waste, we were able to significantly lower overall project costs, making homeownership more attainable for low-income individuals and families.

• Versatility in Construction:

While our primary focus was affordable housing, the modular structure demonstrated versatility across various construction sectors. Its adaptable design and efficient construction made it suitable for multi-family housing developments, single-family homes, and mixed-use projects.

• Conclusion:

The Prefabricated Modular Structure for Affordable Housing project exemplifies the transformative potential of modern construction methods and software-driven innovation. We made significant strides toward creating a more inclusive and sustainable built environment by leveraging advanced software tools and engineering expertise.

• Skills: Revit | AutoCAD | Civil 3D | Fusion 360 | STAADPro | Design Engineering | Structural Analysis | Sustainability Engineering | Affordable Housing Solutions | Project Management | Collaboration | Multi-family Housing | Single-family Housing | Mixed-use Developments | Cross-functional Collaboration

Academic Showcase: Elevated Water Tank Design and Analysis (September 2021)

An academic project focused on the "Design and Analysis of an Elevated Water Tank." 

• Project Overview:

The project centered on the meticulous design and analysis of an elevated water tank capable of storing 600,000 liters (158,503 gallons) of water. This endeavor required a comprehensive understanding of structural engineering principles, hydraulic analysis, and water distribution systems.

• Design Excellence:

The cornerstone of the project was the precise calculation and design of the elevated water tank to meet the area's specific water requirements. Leveraging my expertise in structural engineering, I ensured the tank's design adhered to safety standards and durability considerations.

• Analytical Precision:

To inform the design process, I thoroughly assessed the area's daily and weekly water consumption patterns. This analytical approach allowed me to determine the optimal tank size and capacity to efficiently meet the area's water demands.

• Key Highlights:

1. Capacity and Reliability: The primary objective was to design a water tank capable of reliably storing and distributing 600,000 liters of water, addressing the area's water needs efficiently and reliably.

2. Optimized Resource Utilization: I analyzed daily and weekly water usage patterns and ensured that the water tank's capacity was optimized to balance meeting demand and conserving resources.

3. Engineering Expertise: The project showcased my structural engineering and hydraulic analysis proficiency, highlighting my ability to address complex engineering challenges with practical solutions.

4. Academic Rigor: This project was conducted within the academic framework, adhering to rigorous research methodologies and engineering principles to ensure the highest standards of academic excellence.

5. Practical Relevance: Beyond its academic significance, the project had real-world implications for addressing the community's water needs. By providing a sustainable and reliable water supply, the elevated water tank contributed to the area's welfare and development.

• Conclusion:

This academic project exemplifies my dedication to applying engineering knowledge to solve real-world challenges. It underscores the practical application of engineering principles to enhance the quality of life and foster sustainable development within communities. As a civil engineer, I am committed to leveraging my skills and expertise to make meaningful contributions to society.

• Skills: Structural Engineering | Hydraulic Analysis | Water Distribution Systems | Research Methodologies | Analytical Skills | Problem-Solving | Academic Rigor | Practical Application of Engineering Principles

Construction Material Data Collection and Analysis (January 2020)

A significant project focused on collecting and analyzing construction material data in the Cidco area. This initiative exemplifies my commitment to providing valuable insights for informed decision-making in the construction industry, thereby enhancing project efficiency and productivity.

• Project Overview:

The project commenced to gather comprehensive information on construction materials available in the Cidco area, a crucial aspect of construction planning and procurement. Recognizing the importance of accurate and up-to-date data in construction projects, I embarked on a meticulous data collection process to ensure the integrity and reliability of the information gathered.

• Data Collection:

My primary responsibility was compiling a comprehensive dataset encompassing various construction materials essential for various building projects. Leveraging my expertise in research methodologies and data collection techniques, I systematically gathered information on material types, suppliers, quality standards, pricing, availability, and market dynamics.

• Analytical Approach:

After completing the data collection phase, I transitioned to the analytical stage, where I thoroughly examined the collected data. My analysis focused on key factors such as material quality, pricing trends, availability fluctuations, monthly requirements, and prevailing market dynamics. By employing advanced analytical tools and methodologies, I extracted valuable insights from the dataset to guide decision-making processes in the construction industry.

• Key Highlights:

1. Comprehensive Data: The project compiled an extensive dataset covering a broad spectrum of construction materials, providing stakeholders with a comprehensive overview of available resources in the Cidco area.

2. Quality Assessment: As part of the analysis, I conducted a detailed evaluation of material quality, ensuring that construction materials met industry standards and specifications. This quality assessment was crucial for ensuring the integrity and durability of construction projects.

3. Pricing Strategy: My analysis delved into pricing trends for various construction materials, offering valuable insights into cost-effective procurement strategies. Stakeholders could optimize their purchasing decisions and maximize cost savings by identifying price fluctuations and trends.

4. Supply Chain Insights: Assessing material availability and monthly requirements allowed me to provide valuable insights into supply chain management. Stakeholders could streamline their procurement processes and minimize disruptions by identifying potential bottlenecks and optimizing inventory levels.

5. Market Trends: Tracking market dynamics and trends enabled stakeholders to adapt to evolving industry conditions and anticipate future changes. By staying informed about market developments, construction professionals could make proactive decisions to mitigate risks and capitalize on opportunities.

• Strategic Value:

The project's strategic value lies in its ability to serve as a foundation for informed decision-making in the construction industry. By providing stakeholders with comprehensive data and actionable insights, it empowered them to make choices that aligned with project goals, budgets, and timelines. Additionally, it facilitated collaboration and communication among various stakeholders, fostering a more efficient and productive construction ecosystem in the Cidco area.

• Skills: Data Collection | Data Analysis | Market Research | Quality Assessment | Pricing Analysis | Supply Chain Management | Strategic Decision-Making | Communication | Collaboration

Establishment of Permanent Benchmark and Survey Management (January 2019)

A pivotal project to establish a permanent benchmark and manage surveys from Aurangabad Airport to the MGM Campus. This initiative underscored my expertise in civil engineering principles, particularly in surveying. The project's significance lies in its contribution to accurate data collection, crucial for informed decision-making and the successful execution of construction projects.

• Project Overview:

The project commenced with a thorough assessment of the area's surveying needs, highlighting the necessity for a permanent benchmark along the route from Aurangabad Airport to the MGM Campus. As a civil engineering enthusiast, I recognized the critical role of precise survey data in guiding construction activities and ensuring infrastructure integrity.

• Leadership and Management:

A primary challenge was effectively leading and coordinating a team of surveying professionals. Assuming the role of project leader, I orchestrated the efforts of a multidisciplinary team comprising four skilled individuals. I fostered a collaborative environment conducive to achieving project objectives through clear communication, strategic delegation, and meticulous coordination.

• Benchmark Establishment:

Establishing a permanent benchmark was paramount for providing a reference point for future regional surveying endeavors. Collaborating closely with my team, we identified an optimal location and meticulously conducted measurements and calculations to ensure the benchmark's accuracy and reliability. Adhering to industry standards and leveraging advanced surveying equipment, we established a permanent benchmark of exceptional precision.

• Mean Sea Level Calculation:

In addition to benchmark establishment, calculating the mean sea level of the MGM Campus relative to the benchmark at Aurangabad Airport was crucial. This involved conducting comprehensive surveys and precise measurements to determine elevation variations across the campus. Leveraging advanced surveying techniques and data analysis methodologies, I oversaw collecting and processing survey data to derive accurate mean sea level calculations. This data would serve as a vital reference for future construction and infrastructure planning endeavors within the campus vicinity.

• Contributions to Construction:

The survey data was pivotal in informing the planning and execution of construction projects within the MGM Campus. By providing precise elevation data and reference points, we facilitated the design and implementation of various infrastructure projects, including roads, buildings, and utilities. The MGM Construction Department relied on our survey data to make informed decisions regarding project scope, design specifications, and resource allocation, thereby ensuring the successful completion of construction projects within specified parameters.

• Project Impact:

The establishment of the permanent benchmark and the collection of survey data profoundly impacted construction activities within the MGM Campus. Our efforts provided a solid foundation for informed decision-making and efficient project management. By integrating survey data into construction planning and execution, we contributed to the overall enhancement and development of campus infrastructure.

• Appreciation and Recognition:

Our team's dedication and professionalism garnered appreciation and recognition from key stakeholders, including the Construction Department at MGM and other campus authorities. They expressed gratitude for the quality and significance of the survey data and acknowledged its instrumental role in facilitating construction activities and infrastructure development within the campus. This recognition underscored the value of our contributions and motivated us to continue striving for excellence in our endeavors.

• Value Addition:

Through our surveying efforts and data analysis, we provided essential information for construction projects and advanced surveying techniques and methodologies. Our project exemplified the importance of precise survey data in construction planning and execution, highlighting the indispensable role of civil engineers in shaping the built environment.

• Skills: Survey Management | Leadership | Data Analysis | Benchmark Establishment | Precision Measurement Techniques | Construction Planning and Execution | Collaboration |Communication | Strategic Planning | Infrastructure Development

Structural Design of G+2 R.C.C. Building (December 2018)

• Project Description:

Focused on the structural design of a Ground+2 Reinforced Concrete (R.C.C.) building. This project aimed to showcase my proficiency in structural engineering principles and dedication to adhering to Indian standard codes for building design.

• Design Challenge:

The principal challenge of this project lay in formulating a resilient and structurally sound R.C.C. framed structure tailored for a three-story building. The design necessitated careful consideration of various loads and stresses encountered in multi-story constructions to ensure optimal structural performance.

• Detailed Calculations:

To surmount this challenge, I conducted intricate calculations to ascertain the dimensions of critical structural elements, including beams, columns, slabs, and foundations. These calculations were pivotal in ensuring compliance with the stringent safety and load-bearing standards stipulated by Indian standard codes.

• Code Compliance:

Throughout the design process, I adhered meticulously to Indian standard codes governing building construction. By meticulously following these codes, I upheld the structural integrity of the building to the highest standards, mitigating potential risks and vulnerabilities.

• Key Highlights:

1. Optimization of Structural Elements:

A standout feature of this project was my adeptness in optimizing structural elements to strike a balance between strength, safety, and economy. Through rigorous analysis of diverse design options and consideration of material utilization and structural efficiency, I devised an optimized design solution.

2. Comparative Structural Analysis:

I undertook a comprehensive comparative analysis to assess various facets of the design vis-à-vis Indian standard codes. This analysis facilitated the identification of design strengths and areas necessitating refinement, thereby augmenting my comprehension of structural design principles and best practices.

3. Emphasis on Safety and Efficiency:

Ultimately, the project's primary objective was to engineer a secure and efficient building capable of enduring the test of time. By prioritizing safety considerations and implementing sound engineering methodologies, I ensured that the final design met regulatory requisites and delivered a durable and dependable structure aligned with its intended function.

In essence, the Structural Design of G+2 R.C.C. Building projects epitomized my commitment to excellence in structural engineering and my steadfast dedication to crafting designs that prioritize safety, efficiency, and alignment with industry standards.

• Skills: Structural Engineering | Reinforced Concrete Design | Structural Analysis | Code Compliance (Indian Standard Codes) | Calculation and Dimensioning of Structural Elements | Optimization Techniques | Comparative Structural Analysis | Safety Engineering | Project Management | Communication and Presentation Skills

Road Profile Survey and Alignment Evaluation (August 2018)

• Introduction:

The road profile survey and alignment evaluation project conducted at the Gandheli campus, MGM, in August 2018 was a significant undertaking that showcased my expertise in surveying, alignment determination, and utilizing advanced survey instruments. As a vital member of the surveying team, I played a pivotal role in ensuring the accuracy and precision of the collected data, which would be instrumental in guiding future road construction and maintenance endeavors.

• Project Overview:

The project aimed to conduct a comprehensive survey of the road profile to gather precise alignment and elevation data. This data was crucial for informing construction and maintenance decisions and ensuring the transportation infrastructure's safety, efficiency, and longevity. My responsibilities encompassed overseeing the surveying process, from planning and execution to data analysis and reporting.

• Survey Expertise:

My comprehensive experience in surveying techniques allowed me to manage and execute surveying tasks effectively. I meticulously planned and executed the survey to ensure that each aspect of the road profile was accurately measured and documented. This involved utilizing sophisticated survey instruments and software to capture precise data points, including elevation profiles, cross-sections, and slope gradients.

• Alignment Determination:

Determining the alignment of the road was a critical component of the project. By analyzing the collected data and applying engineering principles, I accurately determined the optimal alignment for the road, considering factors such as topography, drainage, and traffic flow. This information was essential for guiding the design and construction phases of the project, ensuring that the road would meet safety and performance standards.

• Advanced Survey Instruments:

The project allowed us to work with state-of-the-art survey instruments, including total stations. This advanced tools allowed us to collect highly accurate and detailed data, even in challenging terrain conditions. By leveraging these instruments' capabilities, we enhanced the efficiency and accuracy of our surveying efforts, ultimately delivering superior results.

• Key Highlights:

• Accurate Road Profiling:

Through meticulous data collection and analysis, my team and I produced highly accurate road profiling data. This information provided valuable insights into the road's existing conditions, enabling informed decision-making during the design and construction phases.

• Data-Driven Decisions:

The data collected during the survey served as the foundation for making data-driven decisions about road development and infrastructure planning. We empowered project stakeholders to allocate resources effectively and mitigate potential risks by providing reliable and comprehensive data.

• Utilizing Advanced Tools:

The project underscored my commitment to leveraging advanced technology in surveying. By utilizing cutting-edge survey instruments and software, we achieved unparalleled levels of accuracy and precision in our surveying efforts. This enhanced the quality of our deliverables and showcased our proficiency in adopting innovative solutions to complex engineering challenges.

• Conclusion:

The road profile survey and alignment evaluation project exemplified my dedication to excellence in surveying and alignment determination. Through careful planning, meticulous execution, and the utilization of advanced survey instruments, we delivered superior results that met the highest industry standards. I am proud of my contributions to this project and look forward to applying my skills and expertise to future endeavors in the construction and infrastructure development sectors.

• Skills: Surveying | Data Analysis | Road Alignment | Engineering Principles | Advanced Instruments | Data-Driven Decisions | Project Management | Coordination | Quality Assurance | Collaboration | Communication