Wireless Power Transmission Market - Global Industry Size, Share, Trends, Opportunity, and Forecast Segmented By Technology (Near-Field Technology and Far-Field Technology), By Application (Receiver and Transmitter), By Type (Devices with Battery and Devices without Battery), By Region & Competition, 2021-2031F

Forecast Period	2027-2031
Market Size (2025)	USD 8.36 Billion
CAGR (2026-2031)	19.03%
Fastest Growing Segment	Devices with Battery
Largest Market	Asia Pacific
Market Size (2031)	USD 23.78 Billion

Market Overview

The Global Wireless Power Transmission Market will grow from USD 8.36 Billion in 2025 to USD 23.78 Billion by 2031 at a 19.03% CAGR. Wireless power transmission encompasses the transfer of electrical energy from a source to a load without physical connectors, utilizing mechanisms such as inductive coupling, magnetic resonance, or radio frequency. The market growth is primarily sustained by the ubiquitous reliance on battery-powered consumer electronics and the increasing integration of automated charging solutions within the automotive and industrial sectors. These core drivers necessitate efficient, cable-free energy delivery systems that enhance operational mobility, operating independently of transient technological fads.

However, widespread market expansion encounters a significant challenge regarding the inherent efficiency attrition and range limitations of current far-field technologies. According to the Wireless Power Consortium, in early 2025, the Qi2 standard was enabled on over 1.5 billion devices globally. This substantial figure underscores the high penetration of near-field inductive solutions, yet the industry must still address the technical complexities of maintaining power stability over greater distances to fully realize the potential of spatial wireless charging.

Key Market Drivers

The Rapid Expansion of the Electric Vehicle Charging Ecosystem serves as a primary catalyst for market acceleration, shifting the industry focus from low-power consumer applications to high-wattage mobility solutions. As automotive manufacturers prioritize seamless user experiences, high-power dynamic and static wireless transfer systems are being developed to mitigate range anxiety and eliminate physical plug-in requirements. This technological leap is exemplified by recent breakthroughs in power density and speed which are critical for heavy-duty and passenger vehicle adoption. According to Oak Ridge National Laboratory, August 2024, in the 'Wireless EV charging record set with Porsche Taycan prototype' press release, researchers successfully demonstrated a wireless power transfer of 270 kilowatts to a light-duty vehicle, proving that inductive systems can now rival the speed of conventional wired fast chargers.

Concurrent with automotive strides, the Rising Adoption of Wireless Charging in Consumer Electronics is intensifying through the demand for faster, higher-wattage delivery that matches wired capabilities. Manufacturers are aggressively overcoming previous speed limitations to maintain consumer interest in premium devices and ecosystems. For instance, according to Xiaomi, February 2024, in the 'Xiaomi 14 Ultra Launch' announcement, the company introduced a smartphone capable of 80W wireless charging, significantly outpacing legacy Qi speeds. To ensure such high-performance advancements remain efficient and interoperable across the broader market, standardizing bodies are updating critical benchmarks. According to SAE International, August 2024, the revised J2954 standard specification now validates wireless power transfer efficiencies of up to 93 percent, directly addressing historical concerns regarding energy loss in contactless transmission.

Download Free Sample Report

Key Market Challenges

The fundamental impediment to the widespread expansion of the Global Wireless Power Transmission Market is the significant efficiency attrition and range limitations inherent in current far-field technologies. As the physical distance between the transmitter and the receiver increases, the energy transfer rate degrades rapidly due to the physics of radiative propagation, rendering the delivery of high wattage commercially unviable over extended ranges. This technical constraint restricts the deployment of spatial charging primarily to low-power applications, such as small IoT sensors or electronic shelf labels, effectively preventing the technology from penetrating lucrative high-demand sectors like industrial machinery or electric vehicles that require robust, sustained energy streams without proximity.

This disparity creates a distinct performance gap that hampers market value, as the industry can currently only guarantee power stability when the source and load remain nearly touching. This limitation is evident when contrasting long-range capabilities with recent near-field advancements. According to the Wireless Power Consortium, in 2024, the Ki Cordless Kitchen standard was upgraded to support up to 2.2 kW of wireless power delivery. While this figure illustrates the immense potential of wireless energy, the inability to maintain such power density over distance limits the market to localized charging spots rather than enabling a truly cord-free environment, thereby stalling broader infrastructure adoption.

Key Market Trends

The commercialization of long-range RF and microwave power beaming is transforming the market by enabling energy transfer across vast distances and around physical obstacles, fundamentally overcoming historical line-of-sight limitations. This trend is characterized by the deployment of intelligent relay nodes that redirect electromagnetic waves to sustain continuous power links for mobile industrial assets and defense applications. According to Reach Power, November 2024, in the 'Reach Completes Phase II of Future Force Energy Campaign with U.S. Air Force' announcement, the company successfully demonstrated the world’s first wireless power transfer energy relay nodes, proving the capability to route radio frequency beams through multiple segments to extend range and reliability in complex environments.

Simultaneously, the growth of RF energy harvesting networks is driving a paradigm shift towards battery-less IoT ecosystems, particularly within the retail and logistics sectors. This movement focuses on eliminating disposable batteries from billions of connected sensors by installing infrastructure that broadcasts energy to perpetually power electronic shelf labels and asset trackers. This industrial scaling is evidenced by major infrastructure investments. According to Energous Corporation, December 2024, in the 'Energous Awarded Scalable Multi-Phase Contract With Fortune 10 Retailer' press release, the company secured a deal to upgrade approximately 4,700 retail locations with wireless power networks, validating the shift towards maintenance-free, sustainably powered supply chain operations.

Segmental Insights

Based on current market dynamics, the Devices with Battery segment is witnessing the most rapid expansion within the Global Wireless Power Transmission Market. This growth is primarily driven by the increasing integration of wireless receiver technology into consumer electronics, such as smartphones and wearables, to eliminate physical charging ports and enhance device waterproofing. Furthermore, the automotive sector is accelerating this trend by adopting wireless charging systems for electric vehicles to improve charging infrastructure convenience. Standardization initiatives by the Wireless Power Consortium facilitate this widespread adoption by ensuring interoperability across various manufacturers, thereby solidifying the demand for battery-dependent applications.

Regional Insights

Asia Pacific leads the global wireless power transmission market due to the high concentration of consumer electronics manufacturing in China, Japan, and South Korea. The region experiences strong demand for inductive charging technologies integrated into smartphones, wearables, and industrial machinery. Additionally, government mandates promoting electric mobility have accelerated the deployment of wireless charging infrastructure for electric vehicles. Collaborative efforts between local manufacturers and organizations like the Wireless Power Consortium ensure standard compliance, further driving the adoption of these technologies across the residential and automotive sectors.

Recent Developments

• In November 2025, Electreon entered into a Memorandum of Understanding to acquire the assets of InductEV, a United States-based provider of high-power static wireless charging systems. This strategic move aimed to unite Electreon’s dynamic wireless charging technology, which powers vehicles while they move, with InductEV’s ultra-fast static solutions for heavy-duty fleets. The consolidation was intended to create a comprehensive global platform offering a full range of wireless charging products for various vehicle classes, including buses and delivery trucks. The combined portfolio was expected to accelerate fleet electrification by providing versatile infrastructure solutions that enhance the efficiency of electric vehicle operations.
• In June 2025, Energous Corporation launched the e-Sense tag, a new battery-free and maintenance-free wireless sensor solution for the Internet of Things market. This product utilized the company’s proprietary over-the-air wireless power networks to continuously energize asset-tracking devices, removing the reliance on traditional batteries. The introduction of this technology marked a significant expansion of the company’s end-to-end wireless power platform, specifically targeting ambient IoT applications. By negating the need for manual battery replacements, the solution was designed to improve operational efficiency and sustainability for enterprises managing extensive supply chain logistics and asset monitoring systems.
• In October 2024, Rohde & Schwarz announced a strategic collaboration with the AirFuel Alliance to advance the standardization of radio frequency-based wireless power transmission. As part of this partnership, the company developed a comprehensive testing solution designed to validate device conformance to the AirFuel RF standard. This initiative aimed to support the deployment of interoperable wireless power networks that can sustain battery-less devices, thereby reducing environmental waste. The President of the AirFuel Alliance emphasized that the new testing equipment would enable manufacturers to rigorously verify their products, ensuring they meet the necessary performance and safety benchmarks for global adoption.
• In January 2024, WiTricity and ICON EV collaborated to unveil the first electric golf carts equipped with factory-installed wireless charging capabilities. This development, showcased at the Consumer Electronics Show, integrated WiTricity’s magnetic resonance technology into ICON’s low-speed vehicles to offer a seamless "park and charge" experience. The system utilized a specialized receiver mounted on the vehicle and a power hub that connected to standard household outlets, eliminating the need for physical cords. The Chief Executive Officer of WiTricity stated that this expansion into the golf cart market addressed the increasing consumer demand for convenient and autonomous charging solutions.

Key Market Players

• Energous Corporation
• WiTricity Corporation
• Qualcomm Technologies, Inc.
• Samsung Electronics Co., Ltd.
• Texas Instruments Incorporated
• Integrated Device Technology, Inc
• HEVO
• NXP Semiconductors N.V.
• Ossia Inc.
• Broadcom Inc.

By Technology	By Application	By Type	By Region
Near-Field Technology and Far-Field Technology	Receiver and Transmitter	Devices with Battery and Devices without Battery	North America Europe Asia Pacific South America Middle East & Africa

Report Scope:

In this report, the Global Wireless Power Transmission Market has been segmented into the following categories, in addition to the industry trends which have also been detailed below:

• Wireless Power Transmission Market, By Technology:

• Near-Field Technology and Far-Field Technology

• Wireless Power Transmission Market, By Application:

• Receiver and Transmitter

• Wireless Power Transmission Market, By Type:

• Devices with Battery and Devices without Battery

• Wireless Power Transmission Market, By Region:

• North America
• United States
• Canada
• Mexico
• Europe
• France
• United Kingdom
• Italy
• Germany
• Spain
• Asia Pacific
• China
• India
• Japan
• Australia
• South Korea
• South America
• Brazil
• Argentina
• Colombia
• Middle East & Africa
• South Africa
• Saudi Arabia
• UAE