Technological advancements
disrupting the global
construction industry
Coauthored by Eric Ottinger, Harshit Minglani
and Mark Gibson FRICS
Ernst & Young LLP
23 March 2020

 Technological advancements disrupting the global construction industry

Global construction trends and
technological advancements
The world’s rapid transformation from manual processes to digital
technologies is empowering the construction industry. Construction
companies are now provided with unprecedented levels of
transparency, choice and convenience. With enhanced capabilities,
there is an increased demand for higher quality, greater safety and
timely completion of projects. This influx of technological solutions
is mitigating risks and streamlining the building production process.
Digital innovations and megatrends continue to evolve and shape the
future of the construction industry.
This research provides a high-level overview of the technology
landscape and potential future state of the construction industry. It
is the first of a series of papers that will focus on three core areas
identified herein:

1
2
3

Design oriented digital technologies
Industrialized and componentized construction advances
Construction automation — supporting work through
digitization

Realizing the demand
IT and software companies have recognized a demand for digitization
in the construction industry and are expanding their software offerings
to include solutions tailored for many processes. There have been
several innovative construction technologies introduced in the last
decade, including building information modeling (BIM), project
control and scheduling software. Sensors, cameras and drones are
being used to monitor project progress and create smarter buildings.
Automation is to be found in almost every repetitive process and
the industry is seeing a resurgence in industrial manufacturing in
order to compensate for declining on-site construction productivity.
These evolving technologies have directly impacted construction
activities throughout the value chain. Field labor is becoming more
productive, project management is having greater oversight and
executive staff are obtaining better transparency and reporting.
Consequently, as the economy has experienced expansion in the last
few years, the construction sector has regained its momentum since
the great recession, driven by increased demand for infrastructure
and real estate developments. Incorporating and expanding on these
technologies allows for more intelligent planning of construction,
supply chain management and delivery.
2   23 March 2020

 Technological advancements disrupting the global construction industry

The construction industry is experiencing technological innovations throughout the project lifecycle, with
internet of things (IoT) leading at the forefront. In 2019, the IoT industry was estimated at approximately
$270B and is expected to grow at a 26% compound annual growth rate (CAGR) for the forecasted period
through 2025.1 3D printing currently holds the smallest market share of the construction industry,
however is expected substantial growth at 245.9% CAGR.2 Other technologies, such as blockchain, artificial
intelligence (AI) and robotics are also expected to contribute to this growth, at greater than an estimated
30% CAGR. Full-scale digitization may help escalate the construction sector and generate an estimated 1220% in annual cost savings within a decade.³

Construction technologies by market share projected in 2025
Construction
industry
(USD Billion)

Current
State
(2019)

% of global
market in 2019

Projected CAGR
through 2025
(%)

Projected 2025
state

% of global
market in
2025

BIM

4.90

0.04%

12.70%

10.04

0.07%

Digital twin

3.80

0.03%

37.80%

26.07

0.19%

AR and VR

1.60

0.01%

21.80%

5.20

0.04%

Geo-enabled

5.99

0.05%

31.10%

30.41

0.22%

Prefab

115.90

1.04%

5.96%

164.03

1.18%

Modular

121.30

1.08%

6.90%

181.02

1.30%

0.003

0.00%

245.90%

0.51

0.00%

Robotics

0.03

0.00%

38.86%

0.23

0.00%

RPA

0.78

0.01%

31.10%

3.90

0.03%

Facial recognition

3.20

0.03%

16.60%

8.16

0.06%

AI

0.55

0.00%

35.10%

3.30

0.02%

Blockchain

0.39

0.00%

41.40%

3.12

0.02%

269.89

2.41%

26.00%

1,080.00

7.76%

31.60%

59.21

0.43%

3D printing

IoT
Smart buildings

11.40

0.10%

Sources: Pitchbook³, Grand View Research , Market Watch , Research and Markets , Robotics Business
Review7, Markets and Markets2,8
4

5

6

Numbers above were extrapolated from external sources

23 March 2020   3

 Technological advancements disrupting the global construction industry

Design oriented digital technologies
Building information modeling (BIM)
Utilizing BIM has become the most commonly used technology in the
construction industry, from design through project completion and
operation. 73% of US contractors surveyed by Dodge Data & Analytics
reported utilizing BIM, with 79% of those using it on more than
30% of their projects.9 BIM is the process and digital representation
used for modeling and management of the physical and functional
characteristics of a construction project or facility. It is a shared
knowledge resource for information about a facility, forming a reliable
basis for decisions during its life-cycle; with the possibility of existing
from earliest conception to decommissioning.10 BIM can be applied to
create 3D models, and has evolved to additional dimensions, including
schedule (4D), cost estimating (5D), sustainability (6D) and operations
maintenance (7D). It affords a number of benefits, such as more
effective design, enhanced coordination, a reduction in change orders
and a more efficient construction process overall. During design and
construction, BIM offers savings in cost and time, gains in accuracy and
reduction in errors and rework. The estimated savings of total project
cost using BIM is typically between 4% to 6%.10
Critical information can be input to the digital BIM at the earliest
phases of design and planning. BIM allows engineers to easily analyze
alternative scenarios and visualize the entire planned sequence of the
project. This limits waste and allows products to be delivered closer to a
just-in-time model rather than being stock piled onsite. Because of this,
BIM can directly compliment prefab design, supply chain management
and project installation by allowing owners and contractors to identify
impacts to multiple project elements. As the dimensions of BIM have
evolved, it has become a critical input to digital twins.

Digital twin
One of the latest trends in the construction industry is creation of a
digital twin to enable simulation and predictive analytics. The digital
twin enables convergence of the physical and virtual world, where
every process, product or service is represented by producing a digital
replica of a physical asset or living entity.

4   23 March 2020

 Technological advancements disrupting the global construction industry

Digital twin roadmap
1) Design
2) Development and testing
3) Setup and deployment

Data simulations
augment missing
data

2
Data
capture in

Data
simulations
and real-time
data informs
CIM

Data
optimization

Inputs and
fault
detection

1

3

Predictive
analysis informs
operation and
controls

Digital
Twin:

Campus
Information
Model (CIM)
Generate Campus
Information
Model (CIM)

6

4

ML and AI
processes
improve
operations
over time

Digital model
commissions
physical
building

ROI analysis
and
selections

Data calibration
drives
continuous
improvement

Synthesized
data out

5

Data reset creates
continuous
Improvement

Data capture
and
simulation

4) Fine tuning and
analysis
5) Seamless data
aggregation

This allows analysis of data and monitoring of systems to identify and resolve problems before they
occur, prevent downtime, develop new opportunities and plan for the future by utilizing simulations. By
reconstructing an as-built state of a structure in BIM, we can then compare it to as-planned execution and
take corresponding actions to correct any deviations.
Digital twin building simulations can be used to assess the energy demand, indoor environmental quality,
carbon emissions and payback periods of energy management systems over the lifetime of an asset. Once
the building is operational, a digital twin can notify the user of maintenance malfunctions, such as a light
going out in a fire stairwell. The manager can then check the visual representation to locate the exact
positioning of the bulb and the best access route. Strategic benefits will also include automated progress
monitoring, facilities management, root cause analysis, intelligent recommendations, self-tuning, predictive
maintenance, 3D databases of reflective virtual asset information, data collection for AI systems, data
storage and historical recall.

Augmented and virtual reality
Technologies like augmented reality (AR) and virtual reality (VR) have enabled construction companies,
investors and customers to visualize elements of the design, build and post-construction phases of their
projects. AR is a live, direct or indirect view of a physical, real-world environment whose elements are
‘augmented’ by computer-generated sensory input, such as sound, video, graphics or GPS data. VR is an
artificial environment that is created with software and presented to the user with a virtual model of the
real world. VR therefore allows for isolation of the user during prototyping. 2D, CAD and BIM plan sets can

23 March 2020   5

 Technological advancements disrupting the global construction industry

be transformed into a fully immersive augmented and virtual reality, providing a virtual 3D overlay view of
buildings and interiors. This allows stakeholders to obtain an improved understanding of what is to be built,
along with visibility of spatial mapping. Additionally, it can increase customer and investor satisfaction by
allowing a greater degree of input in the initial planning and design phase. Providing full emersion allows for
stakeholders to increase accuracy in projections, optimize training, identify risks and increase safety before
the construction process begins. Subsequently, it can increase reliability while decreasing margin of error.
Usability can consequently be improved earlier than the traditional process of utilizing plan sets.

Geo-enabled technologies
Geo-enabled technologies have unlocked the potential of location data to drive informed decision-making,
process standardization and efficiency. These technologies utilize cameras and sensors to obtain data,
measurements and quantities over the lifecycle of a project. Drones, also known as unmanned vehicles
or remotely piloted aircraft, are becoming increasingly popular to provide onsite digital asset tracking,
continuous spatial inspection and progress monitoring.
Having the ability to capture broad-scale aerial photography and send real-time images, video and data
to computers or mobile devices is expected to be used for simulating a construction environment to test
scenarios and facilitate evidence-based decision making. Such deployment promotes faster planning,
construction work and site safety. In the UAE, contractors are extensively using drones for monitoring and
inspecting sites. In a labor deficient Japan, Komatsu Ltd. began using drones that create 3D maps, extract
blueprints and simulate construction plans. The future of drones on a construction site will help enhance
analytics, schedule management, labor efficiency and promote waste reduction.
360-degree cameras can provide monitoring for enclosed rooms and buildings. These cameras are providing
assistance with waste reduction and tracking materials, equipment and inventory. This technology is
also advancing toward labor productivity tracking and precise real-time spatial measurements. Suffolk
Construction has integrated image recognition software with automated monitoring capability to recognize
construction risks and hazards.
Cameras eventually may be used in optimizing cost management and holding contractors accountable
for design, materials, labor and potential change orders. Sensors have also become increasingly
popular. Gilbane Construction Company has recently adopted a system of wearable sensors that enables
management to analyze construction operations and productivity in real-time. Utilizing these sensors
alongside GPS diagnostics, work can be monitored remotely to help enhance productivity.

6   23 March 2020

 Technological advancements disrupting the global construction industry

Industrialized and componentized
construction advances
Digitally-enhanced manufacturing of componentized
buildings
With a heightened focus on efficiency and faster building methods,
industrialized construction (prefabrication and modular) is on a
growth path and the trend is emerging across the globe. According to
a survey conducted by Commercial Construction Index, “nearly half
(45%) of contractors currently using prefabrication and modularization
techniques have seen increased use in the last three years.9 The
industrialized approach shifts many construction activities away from
the site and allocates these tasks to a factory. Preassembled building
components and modules are then shipped to the construction site
for assembly. While these are not new concepts, opportunities have
compelled developers and contractors to apply prefabrication with
technological innovation to their projects. Pursuing this strategy
helps overcome construction challenges, including speed of delivery,
economic viability, quality and enhancing environmental sustainability.
Many construction companies are applying digitization to prefab and
modular. This will drive further momentum and may eventually lead to
the emergence of one or two market leaders in this space. Technology
is a dominant theme as it continues to reshape conventional property
uses, while transforming the back office and construction supply chain.
Many of these technologies addressed in this paper, such as drones,
3D printing, robotics, AI and IoT, are expected to provide substantial
improvements to industrialization and construction productivity.
The continued impact of disruptive forces — from changing customer
behavior to technology initiatives, changing demographics and
growing competition from non-traditional players like startups and
technology-based businesses — is leading to continued and advancing
change. It seems likely that, over time, componentized or industrialized
construction will become the dominant solution in the industry for
certain asset types, such as multifamily and commercial.

3D printing
Also referred to as additive manufacturing, 3D printing digitally creates
successive layers of materials to produce three dimensional objects
from a digital file. 3D printing has evolved to be a natural fit within the
industry, usable for a variety of suitable materials (notably polymers,
metals, ceramics and concrete) and providing almost limitless freedom
of flexible design.
23 March 2020   7

 Technological advancements disrupting the global construction industry

Realizing reduced costs associated with fabricating complex shapes provide less constraints on architects
and designers. Emerging opportunities include printing piping and fittings, tools and equipment, formwork
for concrete, structural insulated panels, walls with embedded MEP systems and roofs with solar tiles.
3D printing is especially valuable for prefab and modular construction. With the large majority of prefab
construction work done in a factory, it becomes more feasible to add a 3D printer to the production lines.
A 3D printer has the ability to print complete components and modules (integrated with insulation and MEP)
that will eventually be shipped to the construction site. Internationally, 3D printing has evolved to printing
complete houses and offices. In 2014, Winsun, a Chinese company founded by inventor Ma Yihe, built 10
houses of 200sqm in a day using an industrial-scale 3D printing machine. Most recently, MX3D created a
41-foot smart bridge from 3D printing technology utilizing metal alloys. Reduction in construction time,
human surveillance and environmental impact suggest that 3D printing will continue
to become more prevalent.

Physical robots
Robotics that allow complex physical tasks to be performed with minimal human intervention are becoming
more common in the construction industry. There has been extensive development of methods to automate
various trades. Robotics are being utilized for bricklaying, welding and concrete pouring. Employing robots
to perform typical human labor provides construction efficiencies, precision, reduced human labor and
enhanced safety.
Similar to 3D printing, utilizing robots in a prefab factory can be highly effective. Robots have been
contributing to production lines of manufacturing industries for decades, performing repetitive tasks more
efficiently and with greater accuracy than humans. Some prefab construction companies are exploring
robotic capabilities and have begun implementing them in their production factories. Present initiatives
indicate that fully autonomous factories, logistics, transportation, and eventually the complete supply chain,
may be completely automated with robotics.

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 Technological advancements disrupting the global construction industry

Construction automation — supporting
work through digitization
Robotic process automation (RPA)
RPA is one form of automation, commonly used for boring, repetitive
and mundane tasks. Automation takes a current or modified process
and enhances this via the use of digital tools, enabling machines
(computers) to undertake the work previously executed by humans.
It improves speed, accuracy, consistency and cost of executing these
routine tasks.
RPA can change project controls and tasks related to project finance.
For example, financial forecasts may no longer require manual entries
in Excel. Instead, the robots (a ‘bot’ or ‘program’) can collect data from
multiple systems, while algorithms build forecasts based on past and
present data (using predictive analytics). A computer software program
that operates repetitively with rule-based processes, RPA replicates
and collaborates with the actions of a human being, interacting with
the user interface of a computer system. The software is trained to
connect multiple fragmented systems with automation and is based
on functional specifications that can be adjusted. Given a renewal of
the existing IT landscape is not required, a high level of automation
that collects and transforms data can be reached with minimal effort.
The software then allows the capture and interpretation of a business
process in a repetitive, audited and controlled manner. Subsequently,
business and administrative processes can be fully automated and
programmed by a computer to monitor and reduce costs, save time and
enhance reporting.
Briq has developed RPA programs with bots to track and record
city council meeting minutes and permitting issuances across
municipalities. Users receive weekly ‘intent to build’ scores for the
metro area, along with market updates and forecasts. This allows
for real-time information to be shared with developers who look to
capitalize on investment opportunities from a recent entitlement or
rezoning.
EY teams have recently created Payment Application Managed Service
(PAMS), a digitally automated back of house support solution. PAMS
is a cost-efficient construction and facilities management invoice
processing solution for clients with large owned or leased real estate or
infrastructure portfolios.

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 Technological advancements disrupting the global construction industry

Successful digital transformation of a company’s payment application and processing leads to internal
procedures being automated and therefore saving costs, improving controls and enhancing transparency.
PAMS has had many success cases, including automating 72% of payment processes for a global company
and reducing the processing time from 60 to 7 days. This client experienced 40% processing cost savings
and 9% lower total costs for all of their payments. RPA and other forms of automation can supplement
typical human tasks, reduce error rates, enhance controls and eliminate redundant and repetitive tasks.
This may help address some of the skill shortage being experienced by construction in the competitive labor
market.

Facial recognition and biometrics
Facial recognition captures graphical information using multiple data points like distance between the
eyes and facial curves that are unique to individuals. The information is stored utilizing an algorithm in
a database. When accessed, the system scans and matches the facial information by applying it to the
algorithm. Current investment by owners, developers and contractors include facial recognition to enhance
safety at the construction site, access control and productivity monitoring. Using facial recognition, site
access is restricted to workers and authorized personnel. Contractors are also able to use the data from
facial recognition as backup for invoicing.
In 2019, the global facial recognition market was projected to grow from $3.2B to $7.0B by 2024, at a
CAGR of 16.6%.8 As the technology progresses, it can potentially change the landscape of physical security,
payroll systems, project controls and resource optimization, helping to reduce cost and enhance control.
Facial recognition is currently saving Health and Safety International’s building services contracts £140,000
per year.11

Artificial intelligence (AI)
The global AI construction market is also forecasted to grow substantially, from $407.2M in 2018 to $1.8B
by 2023, at a CAGR of 35.1% 3. AI is a label given to computing systems that exhibit the ability to perceive
information, retain it as knowledge, and apply it to making decisions. AI may also interact in ways that seem
natural to humans, while simultaneously learning from those interactions by utilizing machine learning.
Supported by vast amounts of accessible data, advances in AI have allowed for improved learning algorithms
that enable the extraction of deeper levels of meaning. AI can drive productivity improvements as the
systems augment human skillsets and reduce the need for tedious human effort.
The rising demand for AI- and machine learning-based solutions, the increasing need for greater safety and
the ability to reduce production costs are all expected to drive the growth of AI in the construction sector.
Current AI efforts include project schedule optimization through historical data, identifying unsafe worker
behavior through image recognition and classifying signals and patterns to deploy real-time solutions.
This allows AI to prioritize preventative maintenance and prevent unplanned downtime through enhanced
analytical platforms. As this technology progresses, it will optimize project supply chains by tracking and
analyzing complex data, such as providing the ability to employ artificial neural networks to predict cost
overruns.

10   23 March 2020

 Technological advancements disrupting the global construction industry

Blockchain
Blockchain helps provide the construction supply chain increased functionality, efficiency and visibility.
Blockchain is an open public database where transactions are stored in virtual blocks. These blocks are
connected together in a chain, creating a complete history of all transactions that have occurred within
a particular network. Blockchain has the potential to encrypt and protect key elements in construction
operations and supply chains. This technology could potentially handle all contractual relationships using
concepts like smart contracts and electronic verification. Blockchain-enabled distributed ledgers can enable
better transparency and accountability in construction projects by addressing scope creep, contract changes
and elimination of waste to reduce costs.
A grouping of smart contracts can be used to create a decentralized autonomous organization (DAO) that
is operated by rules encoded as computer programs. Smart contracts executed between the client and the
contractor will enhance the design, tender, install, monitoring, certification and handover of the built asset.
By integrating blockchain, a construction company or building maintenance system could function by a
project or building’s DAO placing an order for products and services. Materials are tracked in an undisputable
blockchain ledger and the DAO accepts delivery. Once the DAO calls out a contractor to install the material,
smart contracts release payments as materials and services achieve milestones. Should milestones or
thresholds be missed indicating reduced fees, the automated system would send alert and recommend
course correction. Lastly, the DAO would make final payment to both the supplier and installer from the
owner’s bank account. The DAO could enhance rent collection, corporate expenditures and insurance
payments with autonomous management.

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 Technological advancements disrupting the global construction industry

Internet of things (IoT)
IoT enables the connectivity of assets and big data analytics, providing new insights for project teams
by capturing large amounts of reliable data in real-time. IoT is the network of physical devices, such as
components, appliances, equipment, buildings and vehicles embedded with electronics, software, sensors,
actuators and network connectivity, enabling these objects to collect and exchange data over the internet.
Combining the features of telematics, asset management and connected BIM, along with using radiofrequency identification and tracking devices, could lead to highly increased efficiencies.
The benefits of IoT span across the entire lifecycle of a project and promote sustainable, whole life costing.
Throughout the entire life cycle, machine learning will continue to recognize opportunities and provide
analytics and recommendations to maximize productivity.
Emerging opportunities include installing meters and monitors at the beginning of construction to analyze
output (energy, utilities, labor, etc.) and optimize visibility supply chain interaction and site conditions. IoT
enables green buildings to complete tasks, such as shutting down unnecessary systems when the building
is unoccupied and opening and closing louvers automatically to provide optimal levels of natural light.
Predictive maintenance programs can also be established with IoT. When fitted with sensors, construction
equipment can automatically send notice if any abnormal patterns are detected. This alerts workers to
intervene early to avoid critical down time or further damage.

Smart buildings to smart cities
IoT is the basis and overarching framework for smart buildings, providing a key enabler of new business
models for commercial real estate. With building automation and IoT centralizing control and integrating
all systems in a building (heating, ventilation, lighting, etc.), it augments the complete project life cycle and
establishes the business case for smart buildings. Smart buildings are constructed to provide autonomous
improvement strategies and recommendations (utilizing AI, RPA and machine learning) that enhance the
well-being and productivity of users while simultaneously saving operational costs and increasing building
efficiencies.

12   23 March 2020

 Technological advancements disrupting the global construction industry

Building managers are looking at smart buildings to analyze space users’ needs and move beyond the
traditional lessor/lessee relationships. Smart buildings are planned to transform the business model and
create real estate as a customer service platform. The customer service platform leverages data, machine
learning and integrated building infrastructure to significantly enhance the user experience. To enable the
transformation of a smart building requires a deep understanding of tenants, usage and occupancy patterns,
as well as driving more information from building management systems — all of which can be explored
through various smart building technologies.

Smart buildings integrated with real-time continuous calibration
The complete building performance and asset life cycle

Step 1: Design solutions
integrated into
construction through BIM

Step 2: Construct
buildings using 3D printing
and prefabrication to
increase efficiency

Step 3: Integrate
IOT into
construction and
building operations

Step 4: Data
acquisition
through IOT

Step 5: Prefabricated
structures
transported to
construction site by
autonomous
semi-truck and
assembled using
robots

Process
reset

Step 12: Perform continuous
performance improvement on
calibrated models, simulate
to forecast next time-step
and automate maintenance
regiment building historical
digital data library

Step 6: AI/RPA
automate data
acquisition,
manipulation and
optimization

Step 7: Advanced
calibrated operational
models identify
improvement
opportunities using
fault detection and
diagnosis

Step 11: Building design
models utilize life cycle data
with on-going improvement
decisions in real-time

Step 10: Asset management
algorithms detect optimization
opportunities

Step 9: Components
optimized to improve
building operations

Step 8: Digital twin
monitors building
operations

Created in collaboration with Todd C. Lukesh and Ernst and Young12
New technologies, such as Tesla’s battery packs and solar roof tiles can be incorporated into smart
buildings to enhance energy efficiency and enable the building to be net zero. Net zero establishes that the
total amount of energy consumed by a building is roughly equal to the amount of energy created on-site.
With a battery pack and solar roof tiles, buildings are now able to become completely net zero, create and
store additional energy, which can allow a building to remove itself from the traditional power grid. Surplus
energy can then be sent back to the power grid and require the owner to be compensated. Smart buildings
will consistently analyze energy consumption and determine its distribution during operations.
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 Technological advancements disrupting the global construction industry

Conclusion — implementation of
ConTech and PropTech
The globalization of capital, emerging technologies and changing
demographics require the real estate and construction sectors to
rethink traditional paths to successful management of the built
environment. To remain competitive, companies must explore new
structuring options, improve the efficiency of operations and balance
portfolios to maximize return on investment — all while mastering
digital disruption and gaining a deeper understanding of customer
preferences.
To create a successful digital strategy that will maximize chances of
long-term success, firms should first challenge its strategic direction,
and then define the future state of the organization that will create
lasting value. Only 25% of real estate and construction firms have
a digital strategy and only 9% feel they are prepared for the digital
revolution.13 A key factor in this lack of progress is the minimal profit
margins systemic within the industry. Construction firms typically
have profit margins of 2-3% compared with an average of 20% in other
industries. When profit margins are narrow, spending 1% of revenue
on digital upgrades and innovation can seem like a heavy and risky
investment; however, failing to invest in solutions that could boost
output is counterproductive. The most innovative will invest and gain a
critical strategic advantage over the rest. The World Economic Forum
estimates that a 1% rise in productivity could result in savings of $100B
per year in the construction industry.14 Additionally, many studies have
recognized that the industry wastes up to 30% of all capital injected,
an unsustainable situation in the long term. We expect a few, digitally
focused, construction and real estate organizations to take on these
challenges and to subsequently dominate the global market in the
second half of the century.
New technologies and market competitors continue to emerge.
The rapid evolution of construction and real estate technologies
emphasizes that those who act fast and decisively, embrace disruption,
and focus on achieving long-term flexibility will emerge as the leading
organizations in the future. Companies should include digital in every
aspect of their operations in order to achieve maximum data-driven
insight. This will enable them to identify new opportunities and threats
across their value chains. With technological innovation quickly
expanding, now is the time to embrace disruption, use change to
enhance productivity and efficiencies, and prepare for the progressive
digital evolution within the construction industry.
14   23 March 2020

 Technological advancements disrupting the global construction industry

Coauthors
Mark Gibson   mark.gibson@ey.com
Mark is a Partner with EY and the leader of the America and Western Region of
EY’s Construction and Real Estate Advisory practice. Mark has over 30 years
of experience in construction, development and corporate real estate. He has
managed over $14B and been associated with over $35B worth of construction
projects. He holds a Master of Science in Construction Project Management and is
a Fellow of the Royal Institution of Chartered Surveyors and a Project Management
Professional. Mark sits on The Real Estate Roundtable where he advises US policy
makers (Congress, President).

Eric Ottinger   eric.m.ottinger@ey.com
Eric Ottinger is a Manager in the Construction and Real Estate Advisory Services
practice of Ernst & Young LLP. Eric has over eleven years of experience in
construction management, project management and program management
including entitlements, preconstruction planning, budgeting, cost control,
scheduling, execution, monitoring and controlling, and project close-out. He holds
a Master of Science in Finance and a Master of Science in Strategy & Organization,
is a certified Project Management Professional and an Associate of the Chartered
Association of Building Engineers.

Harshit Minglani   Harshit.minglani@gds.ey.com
Harshit is a Senior Consultant in the Internal Audit practice of EY GDS. Harshit
has over three years of experience in risk-based process reviews, internal audits,
project management, construction management, internal controls, business
process improvements and data analytics. He holds a Master of Business
Administration in Finance and International Business. He has worked on processes
across the construction project life cycle including planning, execution, monitoring
and project close out.

Contact
Erin Patrick Roberts   erin.roberts@ey.com
As EY’s global leader of Engineering and Construction, Erin has a breadth of
experience serving a diverse roster of public companies in the construction,
engineering, oilfield service and manufacturing industries. He holds a Bachelor of
Science in Accounting and Finance and has served as EY’s representative on the
Financial Issues Committee of the Associated General Contractors of America, is on
the organizing board for the AICPA Construction Conference, is a member of the
American Road & Transportation Builders Association and the Houston Chapter of
the Associated Builders and Contractors.

23 March 2020   15

 Technological advancements disrupting the global construction industry

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23 March 2020   17

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