United States Solar Tracker Market Overview, 2030

The solar tracker market in the United States has evolved dramatically, moving from fixed-tilt solar installations to sophisticated single-axis and dual-axis tracking systems. Due to their simplicity and lower initial costs, fixed-tilt systems were initially the market's dominant product. The necessity for greater efficiency, nevertheless, prompted the use of single-axis trackers as utility-scale solar projects spread throughout large open areas, particularly in the southwestern states. Dual-axis trackers, which can track the sun's motion both horizontally and vertically, gained popularity over time because they could optimize energy production throughout the day. The favorable policy environment, especially federal tax incentives like the Investment Tax Credit (ITC), has been a major factor in the widespread use of these advanced tracking systems. The financial benefits of solar trackers have made them a viable choice in utility-scale projects by greatly lowering the cost burden on developers of large-scale projects. The development of tracking systems designed for extreme conditions such as desert solar farms has been significantly influenced by technological advancements in the United States. Among these innovations are intelligent algorithms that optimize panel angles in response to weather and sun position and dust-resistant designs. The fundamental technology behind solar trackers is based on software and sensors that compute the sun's actual position in real time. These systems automatically change the angle of the solar panels to capture the most sunshine, resulting in a 25–35% increase in energy production efficiency over fixed-tilt systems. The proliferation of solar trackers in the U.S. has been greatly influenced by utility-scale solar projects. These huge plants, which frequently cover thousands of acres, employ tracking technology to guarantee high energy yields, which are necessary to satisfy the rising demand for clean energy. Solar trackers are now essential to America's shift to sustainable and reliable renewable energy production.

According to the research report, ""US Solar Tracker Market Overview, 2030,"" published by Bonafide Research, the US Solar Tracker market is anticipated to grow at more than 15.84% CAGR from 2025 to 2030. As the nation speeds up its transition to renewable energy, this growth path is anticipated to persist. The passage of the Inflation Reduction Act (IRA) in 2022 has been a key factor in the growth of this market. The IRA established a collection of incentives, such as Production Tax Credits (PTCs) and extended Investment Tax Credits (ITCs), which particularly favor solar developers that incorporate cutting-edge technologies like solar trackers. For large-scale installations where maximizing energy production is essential for profitability, these incentives have increased the financial appeal of initiatives utilizing tracking systems. Particularly in the area of AI-driven solar tracker alignment systems, technological advances are also driving the market ahead. Based on real-time weather data, shading patterns, and predictive sun-path algorithms, these smart solutions optimize panel angles. Even in harsh conditions, these breakthroughs greatly increase energy efficiency and operational reliability. Key companies like Nextracker and Array Technologies rule the American industry. Both of these companies have distinguished themselves as leaders via innovation, global presence, and strong supply chains. These businesses offer sophisticated single-axis and dual-axis tracking systems designed for utility-scale usage. The creation of hybrid renewable energy farms, in which solar trackers are coupled with wind turbines to produce complementary energy generation profiles, is one of the most prominent trends now developing in the United States. By balancing solar output with wind power, these hybrid systems aid in reducing intermittency concerns, especially in areas with a lot of both resources. This strategy is consistent with the nation's efforts to achieve carbon neutrality and grid stability.

Single-axis trackers and dual-axis trackers make up the majority of the U.S. solar tracker market, with each having a unique function in the development of solar energy nationwide. The most popular type of solar tracker, especially for large-scale utility projects, is the single-axis tracker. These devices move panels along one axis, often mimicking the sun's path from east to west during the course of the day. The reason for their appeal in the U.S. is primarily because they strike a nice balance between cost-effectiveness and efficiency, often resulting in a 15–25% increase in energy production compared to fixed-tilt systems. In the southwestern United States, single-axis trackers have become the default option for utility developers looking for a better return on their investment while minimizing operational complexity, given the region's wide-open spaces. Dual-axis trackers, on the other hand, provide a more sophisticated answer by enabling motion along both the horizontal and vertical axes. Solar panels may directly face the sun all day long and throughout the year thanks to this dual motion, greatly increasing energy collection. Dual-axis systems can produce up to 35–40% more energy than fixed systems. Due to their mechanical complexity, however, these systems are more expensive to install and maintain. Therefore, dual-axis trackers are frequently employed in niche applications like high-efficiency utility projects, remote power systems, and research institutions, where increasing production is more important than lowering initial costs. Due to the large solar farms in the nation and the emphasis on maximizing capital spending in big projects, single-axis trackers are the most prevalent installation type in the American market. The single-axis designs that firms like Nextracker and Array Technologies offer are specifically designed to meet the climate and energy grid needs of the United States. But with the development of AI-based optimization and advanced control systems, dual-axis trackers may see wider use in specialized, high-performance industries, especially those with limited land or high-quality energy needs.

In the United States, the most popular technology by far is solar photovoltaic (PV), which accounts for the bulk of the installed capacity that uses solar trackers. Sunlight is directly converted into electricity by PV panels, which are commonly employed in utility-scale solar farms. When paired with single-axis trackers, PV systems can produce up to 25% more energy than fixed-tilt arrays. In places like California, Texas, and Arizona, PV with trackers is the cornerstone of America's solar revolution due to their modularity, decreasing costs, and simple installation. Although it only accounts for a smaller part of the market, the Concentrated Solar Power (CSP) technique uses solar trackers in a unique way. In contrast to panels, CSP systems use mirrors or lenses to focus sunlight onto a small area, creating heat, which is subsequently used to produce electricity via turbines. CSP almost always uses dual-axis trackers to precisely follow the sun's movement in order to maximize thermal energy capture. Even if development has slowed due to competition from less expensive PV systems, initiatives like the Ivanpah Solar Electric Generating System in California have shown the potential of CSP. For the best performance, concentrated photovoltaic (CPV) systems which use lenses or curved mirrors to concentrate sunlight onto high-efficiency solar cells also depend on dual-axis tracking. Despite the potential for extremely high conversion efficiencies, CPV is still a small market in the United States because of its high cost and susceptibility to soiling and shading. Consequently, the majority of CPV installations are for research or specialized purposes.

The optimum environment for integrating solar trackers, especially single-axis trackers, is in ground-mounted solar systems, particularly those used in utility-scale applications. These systems are used in vast areas, often in states like California, Texas, Nevada, and Arizona, where there are plenty of open, flat terrains. Due to its spacious design, the tracking systems may be positioned with accuracy and move freely, maximizing exposure to sunshine all day. Compared to fixed-tilt systems, ground-mounted installations with trackers can increase energy production by 15–30%, making them the preferred choice for utility companies and large-scale solar developers that are focused on maximizing efficiency and shortening payback times. On the other hand, rooftop-mounted solar panels are more often seen in homes, businesses, and factories. The majority of rooftop systems in the United States employ fixed-tilt or basic adjustable mounts as opposed to motorized trackers because of space restrictions, structural limitations, and esthetic factors. Due to their increased complexity, weight, and maintenance requirements, solar trackers are often not suited for typical rooftop installations. Nevertheless, advancements in lightweight, compact tracking solutions and AI-driven optimization software are gradually making rooftop-mounted trackers viable for certain commercial and industrial roofs where space and structural factors permit. Ground-mounted systems with single-axis trackers will continue to be the mainstay of the U.S. market because of their scalability, ease of maintenance, and higher energy yields. Major players like Nextracker and Array Technologies concentrate their offerings on ground-mounted installations, targeting utility-scale projects where energy efficiency is paramount. In the future, rooftop-mounted trackers may experience little growth in niche categories, but utility-scale ground-mounted installations will continue to drive the expansion of the solar tracker market in the United States.

Considered in this report
• Historic Year: 2019
• Base year: 2024
• Estimated year: 2025
• Forecast year: 2030

Aspects covered in this report
• Solar Tracker Market with its value and forecast along with its segments
• Various drivers and challenges
• On-going trends and developments
• Top profiled companies
• Strategic recommendation

By Technology
• Solar Photovoltaic (PV)
• Concentrated Solar Power (CSP)
• Concentrated Photovoltaic (CPV)

By Installation Type
• Ground-Mounted
• Rooftop-Mounted Show more