[219 Pages Report] The global wireless connectivity market size is estimated to grow from USD 69.0 billion in 2020 to USD 141.1 billion by 2025, at a CAGR of 15.4%. The major factors driving the Wireless Connectivity market’s growth are the increased demand for wireless sensor networks in the development of smart infrastructure, a significant increase in the internet penetration rate, growth in adoption of the internet of things (IoT), increasing trends like work from home and virtual learning pertaining to the COVID-19 pandemic, increased demand for low-power wide-area (LPWA) networks in the IoT applications. High power consumption by wireless sensors, terminals & connected devices, and lack of uniform communication standards act as restraints for the Wireless Connectivity market.
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The actions taken across the globe to control the spread of COVID-19 are extraordinary at the cost of unprecedented economic loss. There is great confusion among policymakers regarding saving lives or the economy. The economies across the globe are crumbling due to the COVID-19 pandemic, where the price of every commodity has fallen significantly. The effects of COVID-19 have a significant impact on every end-use industry, affecting raw material supply, disrupting the electronics value chain, and causing an inflationary risk on products. More positively, the disruption has caused an acceleration of remote working and an increase in focus on evaluating and de-risking the end-to-end value chain. The demand for wireless technologies has increased due to the pandemic as they are helping to connect virtually.
Various wireless communication and positioning technologies, such as drones, cellular positioning systems, and global positioning systems (GPS), ARE used to monitor the transmission of the virus in the outdoor environment. For instance, a network of drones is used to monitor crowds and maintain social distancing in metropolitan areas. Various countries introduced “pandemic drones” to enforce social distancing. Besides, these pandemic drones can monitor temperature, flu, and sneezing and coughing activities in public places. Various indoor positioning technologies such as radio frequency identification (RFID), Wi-Fi, visible light, Zigbee, and Bluetooth can be promising solutions for monitoring the quarantined people and maintaining a safe working environment. One new solution recently developed for this cause is Proximity Trace, which is a sensing-and-communication technology for workforce distance monitoring while continuing essential businesses. In Proximity Trace, a tag is attached to a worker’s hat or worn on a lanyard that transmits real-time alerts when the workers are in close contact
Wireless sensors are expected to gain traction owing to the increased focus of sensor manufacturers on enhancing wireless sensing technology. The plunging cost of sensors, along with the growing trend of process optimization, home automation, and lifestyle improvement, is increasing the adoption of wireless sensor networks (WSNs).
Advancements in various wireless connectivity technologies such as ZigBee, BLE, Z-Wave, and EnOcean are empowering the rapid deployment of wireless sensors in smart homes and offices. Every day, sensors are widely used in several applications ranging from homes to office buildings, while high-end precision sensors are used in several industries and laboratories. Thus, the growing demand for affordable smart wireless sensors is expected to drive the growth of the market for BLE chipset/devices as these devices can be paired with Smart Ready devices.
Sensors and other peripherals are significant power consumers. The energy consumption rate for sensors in a wireless sensor network varies based on the protocols the sensors use for communication. Although technologies such as ultra-low-power processors, tiny mobile sensors, and wireless networking are available, there is a need for efficient power management and optical power consumption in IoT devices. Connectivity load is another critical issue since numerous devices need to be connected at the same time. For instance, an average smart home may contain 50–100 connected appliances, lights, thermostats, and other devices, each with their power requirements. Equipment such as smart meters are also used to make the line power efficient. As a frequent manual replacement of the batteries of thousands of sensors, actuators, and other connected devices within IoT systems is not feasible, the main hurdle is the power management of devices using wireless technologies, such as Wi-Fi.
The demand for wireless technologies is fueled by many developments in the wireless communications industry, such as imminent long-term evolution (LTE), increased adoption of smart devices, higher mobility, and explosive growth in mobile data traffic. New wireless technologies demand more spectrum and more energy. LTE and 5G are the fastest-growing mobile technologies and would continue to evolve in the future. With the growing number of connected devices, the need for high-speed internet connectivity has become one of the most important parameters in digitally advanced workplaces. With 3G becoming the absolute wireless broadband technology and 4G rapidly expanding its prospects across numerous applications, the industry focus has shifted toward the development of the 5G technology. It is anticipated to become the next phase of development across the highly dynamic broadband industry. The 5G network infrastructure would help release connectivity of ≥1 Gbps as speculated by leading network providers
Wireless connectivity simplifies and improves the scale of connected devices. However, the enormous growth in the adoption of smartphones and the rapid increase in public Wi-Fi networks have increased the threat of many hidden risks, such as identity theft, hacking, and jamming.
As the number of connected devices is increasing with the growth in the adoption rate of IoT in several applications, a large volume of data is being generated. There are many different devices already deployed on the same network within organizations. Researchers of Israel-based Check Point Institute for Information Security (CPIIS) revealed that smart lightbulbs could be used by hackers to enter the IoT network and then can collect data from internet networks in homes, businesses, or even smart cities. For this study, the researchers conducted experiments on the Philips Hue range of smart lightbulbs and found CVE-2020-6007 vulnerabilities that enabled hackers to infiltrate networks using either the Wi-Fi network or ZigBee, a low-power wireless protocol used by IoT devices.
LTE Cat–M1 is a cellular technology mainly designed for the Internet of Things (IoT) or machine-to-machine (M2M) communication applications. LTE Category M1 is a less costly alternative to more conventional LTE services, such as Cat 4, which was designed to support throughput at 100 MB/s.
LTE Cat–M1 is a low-power wide-area (LPWA) air interface that connects IoT and M2M devices with medium data rate requirements. Compared to other standard cellular technologies such as 2G, 3G, or LTE Cat 1, LTE Cat-M1 enables longer battery life and extended range and deep penetration in buildings and basements. LTE Cat–M1 supports voice over LTE (VoLTE) connectivity, which is required to support a predictable growth in demand for voice-based interfaces in IoT applications such as health and fitness, retail, transportation, and building services.
The wireless personal area network connectivity technology is based on the IEEE 802.15.4 standard. WPAN is a small area and low bandwidth networking technology that permits communication within a very short range, which is around 10 meters. Technologies supporting WPAN include Bluetooth, ultra-wideband (UWB), ZigBee, Z-Wave, and Thread. ZigBee is used to create personal area networks with small and low-power digital radios. It has a transmission distance of 10–100 meters. ZigBee operates at a frequency of 2.4 GHz. It is preferred for applications that require long battery life, secure networking, robustness, and low data transfer rate.
The growth of the market for WPAN-enabled chipset is driven by the introduction of the 5th generation of Bluetooth wireless technology. Bluetooth 5 is touted to be twice faster for low-power applications than the preceding version, Bluetooth 4.0. The introduction of Bluetooth 5 was a key milestone in the development not only of the standard in general but also for the emergence of services based on Bluetooth beacons. For users, smartphones and tablets that support the standard of Bluetooth 5.0 have been introduced in the market.
Consumer electronics is one of the fastest-growing markets. As smartphones, tablets, and similar devices are periodically updated by manufacturers, and consumers are always looking out for the latest products. The consumer electronics segment is constantly expanding with the introduction of various devices equipped with multiple connectivity technologies. Some of the recent developments in this segment are mentioned below.
The consumer drone market has evolved quickly over the past three years. The industry’s future depends on continuing improvements in network infrastructure and photographic equipment. In December 2018, drone activity grounded hundreds of flights at one of the UK’s busiest airports. The consumer drones market is likely to evolve in more unexpected ways. Consumer robotics include robots designed for entertainment, companionship, or to perform domestic tasks. Social robots are a long way from mass adoption but have gained traction in Japan.
APAC has the world’s largest customer base, and digital technologies adopted in this region have greater potential for transformation. As the IoT market is witnessing healthy growth, the wireless connectivity chip market in APAC is expected to grow at a significant rate since a majority of the global population is concentrated in APAC. Hence, the number of new M2M connections per year, the demand for smart consumer devices, and the need for the industrial revolution are higher in this region. Given the large population base in some of the developing economies such as China, India, and Thailand in APAC, coupled with related issues such as those of healthcare and energy management, the wireless connectivity technologies seem to have more opportunities to improve the standard of living and revolutionize the industrial sector in APAC. Moreover, investments by the governments in the development and modernization of businesses in China and India have increased the penetration rate of IoT-connected devices, which include connectivity ICs.
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Report Metric |
Details |
Market size available for years |
2017—2025 |
Base year |
2019 |
Forecast period |
2020—2025 |
Units |
Value (USD Million/Thousand) |
Segments covered |
Connectivity technology, Type, End use, and Geography |
Geographic regions covered |
North America, Europe, APAC, and RoW |
Companies covered |
Intel Corporation (US), Texas Instruments Incorporated (US), Qualcomm Incorporated (US), Broadcom (US), STMicroelectronics N.V. (Switzerland), NXP Semiconductors N.V. (Netherlands), Microchip Technology Inc. (US), MediaTek Inc. (Taiwan), Cypress Semiconductor Corporation (US), Renesas Electronics Corporation (Japan), EnOcean (Germany), Nexcom International Co., Ltd. (Taiwan), Skyworks Solutions, Inc. (US), Murata Manufacturing Co., Ltd. (Japan), Marvell Technology Group (Bermuda), Nordic Semiconductor (Norway), Expressif Systems (China), CEVA, Inc. (US), Quantenna Communications, Inc. (US), Peraso Technologies, Inc. (Canada), Panasonic Corporation (Japan), BehrTech (Canada), Element 14 (Singapore), Dialog Semiconductor (UK), and Silicon Labs (US) |
This report categorizes the wireless connectivity market based on connectivity technology, type, end-use, and geography.
Major players in the wireless connectivity market are Intel Corporation (US), Texas Instruments Incorporated (US), Qualcomm Incorporated (US), Broadcom (US), STMicroelectronics N.V. (Switzerland), NXP Semiconductors N.V. (Netherlands), Microchip Technology Inc. (US), MediaTek Inc. (Taiwan), Cypress Semiconductor Corporation (US), and Renesas Electronics Corporation (Japan).
What will be the dynamics for the adoption of wireless connectivity systems based on connectivity type?
Wi-Fi has remained one of the most dominant wireless connectivity technologies in consumer electronics and enterprise applications. The demand for Wi-Fi-enabled connected home devices such as video doorbells, thermostats, lighting solutions, smart TVs, refrigerators, washing machines, and music systems increases. The changing lifestyles (connected living) of consumers increase the need to stay connected everywhere and all the time. The use of Wi-Fi in consumer electronics has enabled users to control the devices. Wi-Fi has revolutionized how the user interacts with these devices. All these factors are supporting the growth of the market for chipsets based on Wi-Fi technology.
Which are the major companies in the wireless connectivity market? What are their major strategies to strengthen their market presence?
The wireless connectivity market is highly competitive, with a large number of global and local market players. In 2019, Intel Corporation (US), Texas Instruments Incorporated (US), Qualcomm Incorporated (US), Broadcom (US), and STMicroelectronics N.V. (Switzerland) were the major market players in the wireless connectivity market. These companies operate worldwide and are developing wireless connectivity solutions and systems; they rely on their R&D capabilities and have significant product launches.
Which is the fastest-growing region in the wireless connectivity market?
APAC is expected to be the fastest-growing regional market for wireless connectivity during the forecast period. The rising number of new smartphone users every year, the growing demand for smart consumer devices from developing countries, and the ongoing advancements in industrial communication are the major drivers for the growth of the regional market.
Where will all these developments in the wireless connectivity market take the industry in the mid to long term?
Various wireless communication and positioning technologies, such as drones, cellular positioning systems, and global positioning systems (GPS), will be used to monitor the transmission of the virus in the outdoor environment. For instance, a network of drones is used to monitor crowds and maintain social distancing in metropolitan areas. Various countries introduced “pandemic drones” to enforce social distancing. Besides, these pandemic drones can monitor temperature, flu, and sneezing and coughing activities in public places. Various indoor positioning technologies such as radio frequency identification (RFID), Wi-Fi, visible light, Zigbee, and Bluetooth can be promising solutions for monitoring the quarantined people and maintaining a safe working environment.
What are the drivers and restraints for wireless connectivity market?
A significant increase in the internet penetration rate and increased demand for low-power wide-area (LPWA) networks in IoT applications are also expected to support the growth of the market for wireless connectivity. However, high power consumption by wireless sensors, terminals, and connected devices and lack of uniform communication standards are expected to be the major restraints in the growth of the wireless connectivity market. .
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TABLE OF CONTENTS
1 INTRODUCTION (Page No. - 29)
1.1 STUDY OBJECTIVES
1.2 DEFINITION
1.2.1 INCLUSIONS AND EXCLUSIONS
1.3 STUDY SCOPE
FIGURE 1 MARKETS COVERED
1.4 CURRENCY
1.5 PACKAGE SIZE
1.6 LIMITATIONS
1.7 STAKEHOLDERS
1.8 SUMMARY OF CHANGES
2 RESEARCH METHODOLOGY (Page No. - 33)
2.1 RESEARCH DATA
FIGURE 2 WIRELESS CONNECTIVITY MARKET: RESEARCH DESIGN
2.1.1 SECONDARY DATA
2.1.1.1 Secondary sources
2.1.2 PRIMARY DATA
2.1.2.1 Primary sources
2.1.2.2 Key industry insights
2.1.2.3 Breakdown of primaries
2.2 MARKET SIZE ESTIMATION
FIGURE 3 PROCESS FLOW OF MARKET SIZE ESTIMATION
2.2.1 BOTTOM-UP APPROACH
FIGURE 4 MARKET SIZE ESTIMATION METHODOLOGY: BOTTOM-UP APPROACH
2.2.2 TOP-DOWN APPROACH
FIGURE 5 MARKET SIZE ESTIMATION METHODOLOGY: TOP-DOWN APPROACH
2.3 MARKET BREAKDOWN AND DATA TRIANGULATION
FIGURE 6 DATA TRIANGULATION
2.4 RESEARCH ASSUMPTIONS
3 EXECUTIVE SUMMARY (Page No. - 40)
FIGURE 7 LPWAN-ENABLED CONNECTIVITY TYPE SEGMENT TO REGISTER HIGHEST CAGR BETWEEN 2020 AND 2025
FIGURE 8 LTE CAT-M1 TO BE FASTEST-GROWING CONNECTIVITY TECHNOLOGY SEGMENT IN TERMS OF VOLUME FROM 2020 TO 2025
FIGURE 9 WIRELESS CONNECTIVITY MARKET IN APAC TO EXHIBIT HIGHEST CAGR BETWEEN 2020 AND 2025
4 PREMIUM INSIGHTS (Page No. - 43)
4.1 WIRELESS CONNECTIVITY MARKET, 2020–2025 (USD BILLION)
FIGURE 10 INCREASING DEMAND FOR WIRELESS SENSOR NETWORKS IN DEVELOPMENT OF SMART INFRASTRUCTURE IS DRIVING GROWTH OF WIRELESS CONNECTIVITY MARKET
4.2 WIRELESS CONNECTIVITY MARKET, BY END USE
FIGURE 11 CONSUMER ELECTRONICS SEGMENT HELD LARGEST SHARE OF WIRELESS CONNECTIVITY MARKET IN 2019
4.3 WIRELESS CONNECTIVITY MARKET IN APAC, BY CONNECTIVITY TECHNOLOGY AND COUNTRY
FIGURE 12 WI-FI TECHNOLOGY SEGMENT AND CHINA HELD LARGEST SHARES OF WIRELESS CONNECTIVITY MARKET IN APAC IN 2019
4.4 WIRELESS CONNECTIVITY MARKET, BY REGION
FIGURE 13 APAC TO REGISTER HIGHEST CAGR BETWEEN 2020 AND 2025
5 MARKET OVERVIEW (Page No. - 45)
5.1 INTRODUCTION
5.2 MARKET DYNAMICS
FIGURE 14 MARKET DYNAMICS: WIRELESS CONNECTIVITY MARKET
5.2.1 DRIVERS
FIGURE 15 WIRELESS CONNECTIVITY MARKET DRIVERS AND THEIR IMPACT
5.2.1.1 Increasing demand for wireless sensor networks in the development of smart infrastructure
5.2.1.2 Significant increase in the internet penetration rate
FIGURE 16 NUMBER OF CELLULAR MACHINE-TO-MACHINE CONNECTIONS, 2010–2020 (MILLION)
FIGURE 17 NUMBER OF INTERNET USERS TILL MARCH 2020, BY REGION
5.2.1.3 Growth in adoption of the Internet of Things (IoT)
5.2.1.4 Increasing trends like work from home and virtual learning pertaining to the COVID-19 pandemic
5.2.1.5 Increased demand for low-power wide-area (LPWA) networks in IoT applications
5.2.2 RESTRAINTS
FIGURE 18 WIRELESS CONNECTIVITY MARKET RESTRAINTS AND THEIR IMPACT
5.2.2.1 High power consumption by wireless sensors, terminals, and connected devices
5.2.2.2 Lack of uniform communication standards
5.2.3 OPPORTUNITIES
FIGURE 19 WIRELESS CONNECTIVITY MARKET OPPORTUNITIES AND THEIR IMPACT
5.2.3.1 Development of 5G network
5.2.3.2 Significant financial support from governments across the world for R&D in the Internet of Things
5.2.3.3 Growing need for cross-domain applications
5.2.4 CHALLENGES
FIGURE 20 WIRELESS CONNECTIVITY MARKET CHALLENGES AND THEIR IMPACT
5.2.4.1 Increasing privacy and security concerns in the age of IoT
5.3 COVID-19 IMPACT ANALYSIS ON WIRELESS CONNECTIVITY MARKET
5.4 VALUE CHAIN ANALYSIS
FIGURE 21 VALUE CHAIN ANALYSIS OF WIRELESS CONNECTIVITY ECOSYSTEM: SEMICONDUCTOR PROVIDERS AND CONNECTIVITY PROVIDERS ADD MAXIMUM VALUE
5.5 TECHNOLOGY ANALYSIS
5.6 CASE STUDY ANALYSIS
5.6.1 HEALTHCARE
5.6.2 BUILDING AUTOMATION
5.6.3 RETAIL
5.7 PATENT ANALYSIS
5.8 ECOSYSTEM ANALYSIS
FIGURE 22 WIRELESS CONNECTIVITY MARKET: ECOSYSTEM
5.9 MARKET REGULATIONS
5.10 WIRELESS CONNECTIVITY ASP ANALYSIS
6 WIRELESS CONNECTIVITY MARKET, BY CONNECTIVITY TECHNOLOGY (Page No. - 61)
6.1 INTRODUCTION
FIGURE 23 LTE CAT-M1 TECHNOLOGY SEGMENT TO EXHIBIT HIGHEST CAGR IN WIRELESS CONNECTIVITY MARKET, IN TERMS OF VOLUME, FROM 2020 TO 2025
TABLE 1 WIRELESS CONNECTIVITY MARKET, BY CONNECTIVITY TECHNOLOGY, 2017–2019 (MILLION UNITS)
TABLE 2 WIRELESS CONNECTIVITY MARKET, BY CONNECTIVITY TECHNOLOGY, 2020–2025 (MILLION UNITS)
6.2 WI-FI
TABLE 3 WIRELESS CONNECTIVITY MARKET FOR WI-FI TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 4 WIRELESS CONNECTIVITY MARKET FOR WI-FI TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 5 WIRELESS CONNECTIVITY MARKET FOR WI-FI TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 6 WIRELESS CONNECTIVITY MARKET FOR WI-FI TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.2.1 WI-FI, BY BAND
6.2.1.1 Single-band
6.2.1.1.1 Overlapping channels with limited capacity
6.2.1.2 Dual-band
6.2.1.2.1 High data rate applications such video streaming and gaming
6.2.1.3 Tri-band
6.2.1.3.1 High data transfer rate with negligible congestion
TABLE 7 WIRELESS CONNECTIVITY MARKET FOR WI-FI TECHNOLOGY, BY BAND, 2017–2019 (MILLION UNITS)
TABLE 8 WIRELESS CONNECTIVITY MARKET FOR WI-FI TECHNOLOGY, BY BAND, 2020–2025 (MILLION UNITS)
6.3 BLUETOOTH CLASSIC
6.3.1 USED TO TRANSFER DATA OVER SHORT DISTANCES
TABLE 9 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH CLASSIC TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 10 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH CLASSIC TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 11 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH CLASSIC TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 12 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH CLASSIC TECHNOLOGY, BY REGION, 2020–2022 (USD MILLION)
6.4 BLUETOOTH 4X
6.4.1 OPTIMIZED VERSION OF THE PROPRIETARY WIRELESS BLUETOOTH TECHNOLOGY
TABLE 13 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH 4X TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 14 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH 4X TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 15 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH 4X TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 16 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH 4X TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.5 BLUETOOTH 5X
6.5.1 USED IN WIRELESS HEADPHONES AND OTHER AUDIO HARDWARE
TABLE 17 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH 5X TECHNOLOGY, BY REGION, 2015–2023 (MILLION UNITS)
TABLE 18 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH 5X TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 19 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH 5X TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 20 WIRELESS CONNECTIVITY MARKET FOR BLUETOOTH 5X TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.6 ZIGBEE
6.6.1 PERSONAL AREA NETWORKS WITH SMALL AND LOW-POWER DIGITAL RADIOS
TABLE 21 WIRELESS CONNECTIVITY MARKET FOR ZIGBEE TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 22 WIRELESS CONNECTIVITY MARKET FOR ZIGBEE TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 23 WIRELESS CONNECTIVITY MARKET FOR ZIGBEE TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 24 WIRELESS CONNECTIVITY MARKET FOR ZIGBEE TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.7 Z-WAVE
6.7.1 CREATES WIRELESS MESH NETWORK
TABLE 25 WIRELESS CONNECTIVITY MARKET FOR Z-WAVE TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 26 WIRELESS CONNECTIVITY MARKET FOR Z-WAVE TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 27 WIRELESS CONNECTIVITY MARKET FOR Z-WAVE TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 28 WIRELESS CONNECTIVITY MARKET FOR Z-WAVE TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.8 THREAD
6.8.1 IPV6-BASED MESH NETWORKING PROTOCOL
TABLE 29 WIRELESS CONNECTIVITY MARKET FOR THREAD TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 30 WIRELESS CONNECTIVITY MARKET FOR THREAD TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 31 WIRELESS CONNECTIVITY MARKET FOR THREAD TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 32 WIRELESS CONNECTIVITY MARKET FOR THREAD TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.9 NEAR-FILED COMMUNICATIONS (NFC)
6.9.1 ENABLES COMMUNICATION BETWEEN DEVICES WHEN PLACED IN PROXIMITY
TABLE 33 WIRELESS CONNECTIVITY MARKET FOR NFC TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 34 WIRELESS CONNECTIVITY MARKET FOR NFC TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 35 WIRELESS CONNECTIVITY MARKET FOR NFC TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 36 WIRELESS CONNECTIVITY MARKET FOR NFC TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.10 GLOBAL NAVIGATION SATELLITE SYSTEMS (GNSS)
6.10.1 POPULAR TECHNOLOGY FOR MOBILITY
TABLE 37 WIRELESS CONNECTIVITY MARKET FOR GNSS TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 38 WIRELESS CONNECTIVITY MARKET FOR GNSS TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 39 WIRELESS CONNECTIVITY MARKET FOR GNSS TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 40 WIRELESS CONNECTIVITY MARKET FOR GNSS TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.11 ENOCEAN
6.11.1 USED FOR WIRELESS SENSORS, CONTROLLERS, AND GATEWAYS
TABLE 41 WIRELESS CONNECTIVITY MARKET FOR ENOCEAN TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 42 WIRELESS CONNECTIVITY MARKET FOR ENOCEAN TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 43 WIRELESS CONNECTIVITY MARKET FOR ENOCEAN TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 44 WIRELESS CONNECTIVITY MARKET FOR ENOCEAN TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.12 CELLULAR M2M TECHNOLOGIES
6.12.1 WIRELESS NETWORK DISTRIBUTED OVER LAND AREAS CALLED CELLS
6.12.2 2G
6.12.3 3G
6.12.4 4G+
6.12.5 5G
TABLE 45 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M TECHNOLOGY, BY TECHNOLOGY, 2017–2019 (MILLION UNITS)
TABLE 46 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M TECHNOLOGY, BY TECHNOLOGY, 2020–2025 (MILLION UNITS)
TABLE 47 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 48 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 49 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 50 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.13 UWB (ULTRA-WIDEBAND)
6.13.1 IDEAL FOR SHORT-RANGE DATA TRANSMISSION
TABLE 51 WIRELESS COMMUNICATION MARKET FOR UWB TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 52 WIRELESS COMMUNICATION MARKET FOR UWB TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 53 WIRELESS CONNECTIVITY MARKET FOR UWB TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 54 WIRELESS CONNECTIVITY MARKET FOR UWB TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.14 LORA
6.14.1 LONG-RANGE, LOW-POWER WIRELESS PLATFORM
TABLE 55 WIRELESS CONNECTIVITY MARKET FOR LORA TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 56 WIRELESS CONNECTIVITY MARKET FOR LORA TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 57 WIRELESS CONNECTIVITY MARKET FOR LORA TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 58 WIRELESS CONNECTIVITY MARKET FOR LORA TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.15 SIGFOX
6.15.1 LOW-POWER WIDE-AREA NETWORK COVERAGE
TABLE 59 WIRELESS CONNECTIVITY MARKET FOR SIGFOX TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 60 WIRELESS CONNECTIVITY MARKET FOR SIGFOX TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 61 WIRELESS CONNECTIVITY MARKET FOR SIGFOX TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 62 WIRELESS CONNECTIVITY MARKET FOR SIGFOX TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.16 NB-IOT (NARROWBAND IOT)
6.16.1 LOW COST, WIDE COVERAGE, AND LONG BATTERY LIFE
TABLE 63 WIRELESS CONNECTIVITY MARKET FOR NB IOT TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 64 WIRELESS CONNECTIVITY MARKET FOR NB IOT TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 65 WIRELESS CONNECTIVITY MARKET FOR NB-IOT TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 66 WIRELESS CONNECTIVITY MARKET FOR NB-IOT TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.17 LTE CAT M1
6.17.1 ENABLES LONGER BATTERY LIFE, EXTENDED RANGE, AND DEEP PENETRATION IN BUILDINGS AND BASEMENTS
TABLE 67 WIRELESS CONNECTIVITY MARKET FOR LTE-CAT M1 TECHNOLOGY, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 68 WIRELESS CONNECTIVITY MARKET FOR LTE-CAT M1 TECHNOLOGY, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 69 WIRELESS CONNECTIVITY MARKET FOR LTE-CAT M1 TECHNOLOGY, BY REGION, 2017–2019 (USD MILLION)
TABLE 70 WIRELESS CONNECTIVITY MARKET FOR LTE-CAT M1 TECHNOLOGY, BY REGION, 2020–2025 (USD MILLION)
6.18 OTHERS
TABLE 71 WIRELESS CONNECTIVITY MARKET FOR OTHER TECHNOLOGIES, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 72 WIRELESS CONNECTIVITY MARKET FOR OTHER TECHNOLOGIES, BY REGION, 2020–2025 (MILLION UNITS)
TABLE 73 WIRELESS CONNECTIVITY MARKET FOR OTHER TECHNOLOGIES, BY REGION, 2017–2019 (USD MILLION)
TABLE 74 WIRELESS CONNECTIVITY MARKET FOR OTHER TECHNOLOGIES, BY REGION, 2020–2025 (USD MILLION)
7 WIRELESS CONNECTIVITY MARKET, BY TYPE (Page No. - 105)
7.1 INTRODUCTION
FIGURE 24 WPAN-ENABLED CHIPSETS SEGMENT TO DOMINATE WIRELESS CONNECTIVITY MARKET FROM 2020 TO 2025
TABLE 75 WIRELESS CONNECTIVITY MARKET, BY TYPE, 2017–2019 (MILLION UNITS)
TABLE 76 WIRELESS CONNECTIVITY MARKET, BY TYPE, 2020–2025 (MILLION UNITS)
TABLE 77 WIRELESS CONNECTIVITY MARKET, BY TYPE, 2017–2019 (USD MILLION)
TABLE 78 WIRELESS CONNECTIVITY MARKET, BY TYPE, 2020–2025 (USD MILLION)
7.2 WIRELESS LOCAL AREA NETWORK (WLAN)
7.2.1 EXPONENTIAL GROWTH IN BANDWIDTH AND HIGHER THROUGHPUT HAVE FUELED GROWTH OF WLAN TECHNOLOGY SEGMENT
TABLE79 WIRELESS CONNECTIVITY MARKET FOR WLAN, BY REGION, 2017–2019 (MILLION UNITS)
TABLE80 WIRELESS CONNECTIVITY MARKET FOR WLAN, BY REGION, 2020–2025 (MILLION UNITS)
TABLE81 WIRELESS CONNECTIVITY MARKET FOR WLAN, BY REGION, 2017–2019 (USD MILLION)
TABLE82 WIRELESS CONNECTIVITY MARKET FOR WLAN, BY REGION, 2020–2025 (USD MILLION)
7.3 WIRELESS PERSONAL AREA NETWORK (WPAN)
7.3.1 HIGH ADOPTION OF WPAN TECHNOLOGY IS ATTRIBUTED TO ITS LOW COST, FLEXIBILITY, SECURITY, AND EASE OF USE
TABLE83 WIRELESS CONNECTIVITY MARKET FOR WPAN, BY REGION, 2017–2019 (MILLION UNITS)
TABLE84 WIRELESS CONNECTIVITY MARKET FOR WPAN, BY REGION, 2020–2025 (MILLION UNITS)
TABLE85 WIRELESS CONNECTIVITY MARKET FOR WPAN, BY REGION, 2017–2019 (USD MILLION)
TABLE86 WIRELESS CONNECTIVITY MARKET FOR WPAN, BY REGION, 2020–2025 (USD MILLION)
7.4 SATELLITE (GNSS)
7.4.1 GNSS TECHNOLOGY IS WIDELY USED FOR NAVIGATION SOLUTIONS
TABLE87 WIRELESS CONNECTIVITY MARKET FOR GNSS, BY REGION, 2017–2019 (MILLION UNITS)
TABLE88 WIRELESS CONNECTIVITY MARKET FOR GNSS, BY REGION, 2020–2025 (MILLION UNITS)
TABLE89 WIRELESS CONNECTIVITY MARKET FOR GNSS, BY REGION, 2017–2019 (USD MILLION)
TABLE90 WIRELESS CONNECTIVITY MARKET FOR GNSS, BY REGION, 2020–2025 (USD MILLION)
7.5 LOW-POWER WIDE-AREA NETWORK (LPWAN)
7.5.1 LOW POWER CONSUMPTION OF LPWAN TECHNOLOGY MAKES IT IDEAL FOR MANY APPLICATIONS
TABLE91 WIRELESS CONNECTIVITY MARKET FOR LPWAN, BY REGION, 2017–2019 (MILLION UNITS)
TABLE92 WIRELESS CONNECTIVITY MARKET FOR LPWAN, BY REGION, 2020–2025 (MILLION UNITS)
TABLE93 WIRELESS CONNECTIVITY MARKET FOR LPWAN, BY REGION, 2017–2019 (USD MILLION)
TABLE94 WIRELESS CONNECTIVITY MARKET FOR LPWAN, BY REGION, 2020–2025 (USD MILLION)
7.6 CELLULAR M2M
7.6.1 GROWTH OF CELLULAR M2M TECHNOLOGY SEGMENT IS MAINLY DRIVEN BY INCREASING ADOPTION OF 5G
TABLE95 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M, BY REGION, 2017–2019 (MILLION UNITS)
TABLE96 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M, BY REGION, 2020–2025 (MILLION UNITS)
TABLE97 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M, BY REGION, 2017–2029 (USD MILLION)
TABLE98 WIRELESS CONNECTIVITY MARKET FOR CELLULAR M2M, BY REGION, 2020–2025 (USD MILLION)
8 WIRELESS CONNECTIVITY MARKET, BY END USE (Page No. - 120)
8.1 INTRODUCTION
FIGURE 25 CONSUMER ELECTRONICS SEGMENT TO DOMINATE WIRELESS CONNECTIVITY MARKET BETWEEN 2020 AND 2025
TABLE 99 WIRELESS CONNECTIVITY MARKET, BY END USE, 2017–2019 (MILLION USD)
TABLE 100 WIRELESS CONNECTIVITY MARKET, BY END USE, 2020–2025 (MILLION USD)
8.2 WEARABLE DEVICES
8.2.1 HIGH DEMAND FOR SMARTWATCHES, HEARABLES, AND HEAD-MOUNTED DISPLAYS IS DRIVING MARKET GROWTH
8.3 HEALTHCARE
8.3.1 INCREASING TREND OF REMOTE HEALTH MONITORING IS SUPPORTING MARKET GROWTH
8.4 CONSUMER ELECTRONICS
8.4.1 HIGH ADOPTION OF SMART APPLIANCES, SMARTPHONES, AND LAPTOPS IS DRIVING GROWTH OF WIRELESS CONNECTIVITY MARKET
8.5 BUILDING AUTOMATION
8.5.1 MARKET GROWTH IS INFLUENCED BY INCREASING SMART CITY PROJECTS ACROSS THE GLOBE
8.6 AUTOMOTIVE & TRANSPORTATION
8.6.1 EXPANDING CONNECTED CARS MARKET
8.7 OTHERS
8.7.1 INCREASING APPLICATIONS OF IOT IN INDUSTRIAL AND BFSI SEGMENTS
9 GEOGRAPHIC ANALYSIS (Page No. - 126)
9.1 INTRODUCTION
FIGURE 26 WIRELESS CONNECTIVITY MARKET, BY GEOGRAPHY
FIGURE 27 APAC TO DOMINATE WIRELESS CONNECTIVITY MARKET DURING FORECAST PERIOD
TABLE 102 WIRELESS CONNECTIVITY MARKET, BY REGION, 2020–2025 (USD MILLION)
TABLE 103 WIRELESS CONNECTIVITY MARKET, BY REGION, 2017–2019 (MILLION UNITS)
TABLE 104 WIRELESS CONNECTIVITY MARKET, BY REGION, 2020–2025 (MILLION UNITS)
9.2 NORTH AMERICA
FIGURE 28 NORTH AMERICA WIRELESS CONNECTIVITY MARKET SNAPSHOT
TABLE106 WIRELESS CONNECTIVITY MARKET IN NORTH AMERICA, BY CONNECTIVITY TECHNOLOGY, 2017–2019 (MILLION UNITS)
TABLE107 NORTH AMERICAN WIRELESS CONNECTIVITY MARKET FOR WI-FI TECHNOLOGY, BY BAND, 2017–2019 (MILLION UNITS)
TABLE108 NORTH AMERICAN WIRELESS CONNECTIVITY MARKET FOR WI-FI TECHNOLOGY, BY BAND, 2020–2025 (MILLION UNITS)
TABLE109 WIRELESS CONNECTIVITY MARKET IN NORTH AMERICA, BY TYPE, 2017–2019 (MILLION UNITS)
TABLE110 WIRELESS CONNECTIVITY MARKET IN NORTH AMERICA, BY TYPE, 2020–2025 (MILLION UNITS)
TABLE111 WIRELESS CONNECTIVITY MARKET IN NORTH AMERICA, BY TYPE, 2017–2019 (USD MILLION)
TABLE112 WIRELESS CONNECTIVITY MARKET IN NORTH AMERICA, BY TYPE, 2020–2025 (USD MILLION)
TABLE113 WIRELESS CONNECTIVITY MARKET IN NORTH AMERICA, BY COUNTRY, 2017–2019 (MILLION UNITS)
TABLE114 WIRELESS CONNECTIVITY MARKET IN NORTH AMERICA, BY COUNTRY, 2020–2025 (MILLION UNITS)
TABLE115 WIRELESS CONNECTIVITY MARKET IN NORTH AMERICA, BY COUNTRY, 2017–2019 (USD MILLION)
TABLE116 WIRELESS CONNECTIVITY MARKET IN NORTH AMERICA, BY COUNTRY, 2020–2025 (USD MILLION)
9.2.1 US
9.2.1.1 High adoption of smart homes, smart appliances, and connected cars
9.2.2 CANADA
9.2.2.1 Growing adoption of advance technologies by small and medium enterprises to drive market growth
9.2.3 MEXICO
9.2.3.1 Increasing use of advance technologies by traditional companies
9.3 EUROPE
FIGURE 29 EUROPE WIRELESS CONNECTIVITY MARKET SNAPSHOT
TABLE117 WIRELESS CONNECTIVITY MARKET IN EUROPE, BY CONNECTIVITY TECHNOLOGY, 2017–2019 (MILLION UNITS)
TABLE118 WIRELESS CONNECTIVITY MARKET IN EUROPE, BY CONNECTIVITY TECHNOLOGY, 2020–2025 (MILLION UNITS)
TABLE119 WIRELESS CONNECTIVITY MARKET IN EUROPE FOR WI-FI TECHNOLOGY, BY BAND, 2017–2019 (MILLION UNITS)
TABLE120 WIRELESS CONNECTIVITY MARKET IN EUROPE FOR WI-FI TECHNOLOGY, BY BAND, 2020–2025 (MILLION UNITS)
TABLE121 WIRELESS CONNECTIVITY MARKET IN EUROPE, BY TYPE, 2017–2019 (MILLION UNITS)
TABLE122 WIRELESS CONNECTIVITY MARKET IN EUROPE, BY TYPE, 2020–2025 (MILLION UNITS)
TABLE123 WIRELESS CONNECTIVITY MARKET IN EUROPE, BY TYPE, 2017–2019 (USD MILLION)
TABLE124 WIRELESS CONNECTIVITY MARKET IN EUROPE, BY TYPE, 2020–2025 (USD MILLION)
TABLE125 WIRELESS CONNECTIVITY MARKET IN EUROPEAN, BY COUNTRY, 2017–2019 (MILLION UNITS)
TABLE126 WIRELESS CONNECTIVITY MARKET IN EUROPEAN, BY COUNTRY, 2020–2025 (MILLION UNITS)
TABLE127 WIRELESS CONNECTIVITY MARKET IN EUROPEAN, BY COUNTRY, 2017–2019 (USD MILLION)
TABLE128 WIRELESS CONNECTIVITY MARKET IN EUROPEAN, BY COUNTRY, 2020–2025 (USD MILLION)
9.3.1 UK
9.3.1.1 Growing adoption of wireless technologies in consumer applications
9.3.2 FRANCE
9.3.2.1 Increasing investments in R&D to modernize industrial sector is fueling market growth
9.3.3 GERMANY
9.3.3.1 Increasing deployment of smart factory solutions due to adoption of Industry 4.0
9.3.4 ITALY
9.3.4.1 High focus on digital development
9.3.5 REST OF EUROPE
9.4 ASIA PACIFIC (APAC)
FIGURE 30 APAC WIRELESS CONNECTIVITY MARKET SNAPSHOT
TABLE129 WIRELESS CONNECTIVITY MARKET IN APAC, BY CONNECTIVITY TECHNOLOGY, 2017–2019 (MILLION UNITS)
TABLE130 WIRELESS CONNECTIVITY MARKET IN APAC, BY CONNECTIVITY TECHNOLOGY, 2020–2025 (MILLION UNITS)
TABLE131 WIRELESS CONNECTIVITY MARKET IN APAC FOR WI-FI TECHNOLOGY, BY BAND, 2017–2019 (MILLION UNITS)
TABLE132 WIRELESS CONNECTIVITY MARKET IN APAC FOR WI-FI TECHNOLOGY, BY BAND, 2020–2025 (MILLION UNITS)
TABLE133 WIRELESS CONNECTIVITY MARKET IN APAC, BY TYPE, 2017–2019 (MILLION UNITS)
TABLE134 WIRELESS CONNECTIVITY MARKET IN APAC, BY TYPE, 2020–2025 (MILLION UNITS)
TABLE135 WIRELESS CONNECTIVITY MARKET IN APAC, BY TYPE, 2017–2019 (USD MILLION)
TABLE136 WIRELESS CONNECTIVITY MARKET IN APAC, BY TYPE, 2020–2025 (USD MILLION)
TABLE137 WIRELESS CONNECTIVITY MARKET IN APAC, BY COUNTRY, 2017–2019 (MILLION UNITS)
TABLE138 WIRELESS CONNECTIVITY MARKET IN APAC, BY COUNTRY, 2020–2025 (MILLION UNITS)
TABLE139 WIRELESS CONNECTIVITY MARKET IN APAC, BY COUNTRY, 2017–2019 (USD MILLION)
TABLE140 WIRELESS CONNECTIVITY MARKET IN APAC, BY COUNTRY, 2020–2025 (USD MILLION)
9.4.1 CHINA
9.4.1.1 Growing adoption of IoT technology
9.4.2 JAPAN
9.4.2.1 Increasing use of wireless connectivity solutions in IoT applications
9.4.3 SOUTH KOREA
9.4.3.1 Advancements in cellular technologies
9.4.4 REST OF APAC
9.5 REST OF THE WORLD (ROW)
FIGURE 31 ROW WIRELESS CONNECTIVITY MARKET SNAPSHOT
TABLE 141 WIRELESS CONNECTIVITY MARKET IN ROW, BY CONNECTIVITY TECHNOLOGY, 2017–2019 (MILLION UNITS)
TABLE142 WIRELESS CONNECTIVITY MARKET IN ROW, BY CONNECTIVITY TECHNOLOGY, 2020–2025 (MILLION UNITS)
TABLE143 WIRELESS CONNECTIVITY MARKET IN ROW FOR WI-FI TECHNOLOGY, BY BAND, 2017–2019 (MILLION UNITS)
TABLE144 WIRELESS CONNECTIVITY MARKET IN ROW FOR WI-FI TECHNOLOGY, BY BAND, 2020–2025 (MILLION UNITS)
TABLE145 WIRELESS CONNECTIVITY MARKET IN ROW, BY TYPE, 2017–2019 (MILLION UNITS)
TABLE146 WIRELESS CONNECTIVITY MARKET IN ROW, BY TYPE, 2020–2025 (MILLION UNITS)
TABLE147 WIRELESS CONNECTIVITY MARKET IN ROW, BY TYPE, 2017–2019 (USD MILLION)
TABLE148 WIRELESS CONNECTIVITY MARKET IN ROW, BY TYPE, 2020–2025 (USD MILLION)
TABLE149 WIRELESS CONNECTIVITY MARKET IN ROW, BY COUNTRY, 2017–2019 (MILLION UNITS)
TABLE150 WIRELESS CONNECTIVITY MARKET IN ROW, BY COUNTRY, 2020–2025 (MILLION UNITS)
TABLE151 WIRELESS CONNECTIVITY MARKET IN ROW, BY COUNTRY, 2017–2019 (USD MILLION)
TABLE152 WIRELESS CONNECTIVITY MARKET IN ROW, BY COUNTRY, 2020–2025 (USD MILLION)
9.5.1 MIDDLE EAST & AFRICA
9.5.2 SOUTH AMERICA
10 COMPETITIVE LANDSCAPE (Page No. - 162)
10.1 OVERVIEW
FIGURE 32 COMPANIES IN WIRELESS CONNECTIVITY MARKET ADOPTED PRODUCT LAUNCHES AS KEY GROWTH STRATEGY
10.2 MARKET EVALUATION FRAMEWORK
FIGURE 33 MARKET EVALUATION FRAMEWORK: 2018 AND 2019 WITNESSED PRODUCT/SOLUTION LAUNCHES
10.3 KEY MARKET DEVELOPMENTS
10.3.1 PRODUCT LAUNCHES AND DEVELOPMENTS
TABLE 153 10 MOST RECENT PRODUCT LAUNCHES IN WIRELESS CONNECTIVITY MARKET
10.3.2 PARTNERSHIPS, ACQUISITIONS, COLLABORATIONS, AND AGREEMENTS
TABLE 154 10 MOST RECENT PARTNERSHIPS, COLLABORATIONS, ACQUISITIONS, AND AGREEMENTS IN WIRELESS CONNECTIVITY MARKET
11 COMPANY EVALUATION MATRIX AND COMPANY PROFILES (Page No. - 168)
11.1 OVERVIEW
11.2 MARKET RANKING
FIGURE 34 TOP 5 PLAYERS IN WIRELESS CONNECTIVITY MARKET
11.3 COMPANY SHARE ANALYSIS
11.3.1 WI-FI MARKET SHARE ANALYSIS, 2019
11.3.2 NB-IOT MARKET SHARE ANALYSIS, 2019
11.4 COMPANY EVALUATION MATRIX, 2019
11.4.1 STAR
11.4.2 PERVASIVE
11.4.3 EMERGING LEADER
FIGURE 35 COMPANY EVALUATION MATRIX, 2019
11.5 COMPANY PROFILES
(Business Overview, Products/Solutions Offered, Recent Developments, SWOT Analysis, and MnM View)*
11.5.1 INTEL CORPORATION
FIGURE 36 INTEL CORPORATION: COMPANY SNAPSHOT
11.5.2 TEXAS INSTRUMENTS INCORPORATED
FIGURE 37 TEXAS INSTRUMENTS INCORPORATED: COMPANY SNAPSHOT
11.5.3 QUALCOMM INCORPORATED
FIGURE 38 QUALCOMM INCORPORATED: COMPANY SNAPSHOT
11.5.4 BROADCOM
FIGURE 39 BROADCOM: COMPANY SNAPSHOT
11.5.5 STMICROELECTRONICS N.V.
FIGURE 40 STMICROELECTRONICS N.V.: COMPANY SNAPSHOT
11.5.6 NXP SEMICONDUCTORS N.V.
FIGURE 41 NXP SEMICONDUCTORS N.V.: COMPANY SNAPSHOT
11.5.7 MICROCHIP TECHNOLOGY INC.
FIGURE 42 MICROCHIP TECHNOLOGY INC.: COMPANY SNAPSHOT
11.5.8 MEDIATEK INC.
FIGURE 43 MEDIATEK INC.: COMPANY SNAPSHOT
11.5.9 CYPRESS SEMICONDUCTOR CORPORATION
FIGURE 44 CYPRESS SEMICONDUCTOR CORPORATION: COMPANY SNAPSHOT
11.5.10 RENESAS ELECTRONICS CORPORATION
FIGURE 45 RENESAS ELECTRONICS CORPORATION: COMPANY SNAPSHOT
* Business Overview, Products/Solutions Offered, Recent Developments, SWOT Analysis, and MnM View might not be captured in case of unlisted companies.
11.6 OTHER KEY PLAYERS
11.6.1 ENOCEAN
11.6.2 NEXCOM INTERNATIONAL CO., LTD.
11.6.3 SKYWORKS SOLUTIONS, INC.
11.6.4 MURATA MANUFACTURING CO., LTD.
11.6.5 MARVELL TECHNOLOGY GROUP
11.6.6 NORDIC SEMICONDUCTOR
11.6.7 EXPRESSIF SYSTEMS
11.6.8 CEVA, INC.
11.6.9 QUANTENNA COMMUNICATIONS, INC.
11.6.10 PERASO TECHNOLOGIES, INC.
11.6.11 PANASONIC CORPORATION
11.6.12 BEHRTECH
11.6.13 ELEMENT 14
11.6.14 DIALOG SEMICONDUCTOR
11.6.15 SILICON LABS
12 APPENDIX (Page No. - 213)
12.1 DISCUSSION GUIDE
12.2 KNOWLEDGE STORE: MARKETSANDMARKETS’ SUBSCRIPTION PORTAL
12.3 AVAILABLE CUSTOMIZATIONS
12.4 RELATED REPORTS
12.5 AUTHOR DETAILS
The study involved four major activities in estimating the current size of the Wireless Connectivity market. Exhaustive secondary research has been conducted to collect information about the market, the peer market, and the parent market. Validating findings, assumptions, and sizing with industry experts through primary research has been the next step. Both top-down and bottom-up approaches have been employed to estimate the total market size. After that, market breakdown and data triangulation methods have been used to estimate the market size of segments and subsegments.
The research methodology used to estimate and forecast the size of the Wireless Connectivity market begins with capturing data on revenues of the key vendors in the market through secondary research. In the secondary research process, various secondary sources have been referred to identify and collect information relevant to this study. Secondary sources include annual reports, press releases, and investor presentations of companies; white papers, certified publications, and articles from recognized authors; directories; and databases. Secondary research has been carried out to mainly obtain critical information about the industry’s supply chain, value chain, the total pool of key players, and market classification and segmentation according to industry trends, geographic markets, and key developments from both market- and technology oriented perspectives.
In the primary research process, various primary sources from both the supply and demand sides have been interviewed to obtain the qualitative and quantitative information relevant to this report. Primary sources from the supply side include experts such as CEOs, VPs, marketing directors, technology and innovation directors, application developers, application users, and related executives from various key companies and organizations operating in the ecosystem of the Wireless Connectivity market. Primary sources from the demand side include chief information officers, technicians and technologists, and purchase managers of hardware components used in IoT, such as sensors and gateways.
To know about the assumptions considered for the study, download the pdf brochure
Top-down and bottom-up approaches have been used to estimate and validate the size of the Wireless Connectivity market and various other dependent submarkets. Key players in the market have been identified through secondary research, and their market shares in the respective regions have been determined through primary and secondary research. This entire research methodology includes the study of annual and financial reports of top players, as well as interviews with experts (such as CEOs, VPs, directors, and marketing executives) for key insights (both quantitative and qualitative). All percentage shares, splits, and breakdowns have been determined using secondary sources and verified through primary sources. All the possible parameters that influence the markets covered in this research study have been accounted for, viewed in detail, verified through primary research, and analyzed to obtain the final quantitative and qualitative data. This data has been consolidated and supplemented with detailed inputs and analysis from MarketsandMarkets and presented in this report. The figures in the next sections show the overall market size estimation process employed for this study.
After arriving at the overall market size through the processes explained in the earlier sections, the total Wireless Connectivity market has been split into several segments. To complete the overall market engineering process and arrive at the exact statistics for all segments, market breakdown and data triangulation procedures have been employed, wherever applicable. The data has been triangulated by studying various factors and trends from both the demand and supply sides. Moreover, the market has been validated using both the top-down and bottom-up approaches.
With the given market data, MarketsandMarkets offers customizations according to the company’s specific needs. The following customization options are available for the Wireless Connectivity market report.
Growth opportunities and latent adjacency in Wireless Connectivity Market
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