The study conducted on 5G mmWave chipset market (5G Millimeter Wave ICs) provides an in-depth analysis (118 Pages and 125 Exhibits) on current 5G mmWave deployments, ecosystem, spectrum, market overview, evolution, drivers & challenges, use cases, and cost analysis. The study is focussed on mmWave 5G chipset value chain that includes mmWave 5G baseband processor/modem, RF transceiver, and RF front end suppliers.
As per this latest market report, 5G mmWave chipset market is expected to reach $56.3 billion by 2026, at a CAGR of 37.3% in next 5 years. 5G mmWave chipset includes baseband processor/modem and RFIC components such as RF transceivers and RF front end. Mobile devices are expected to be the major contributors in mmWave 5G chipset market because of growing availability of 5G mmWave enabled smartphones and other consumer devices.
mmWave delivers wide spectrum and capacity over the shortest distances for 5G along with lower latencies. High bands above 24GHz are allocated for 5G telecom infrastructure. The availability of the new spectrum depends on how much spectrum is released by regulators for use by service providers. Spectrum allocations for mmWave are often extremely wide, with 800 MHz or more per service provider and band. Wide spectrum enables the provision of high-capacity delivery and improved handling of peak rates. The US market is a global leader in the use of mmWave spectrum for 5G, with all major US operators already offering commercial 5G services using the band. Limited 5G mmWave deployments has been witnesses in Asia Pacific while Europe is far behind.
5G chipsets are poised to become an integral part of the 5G-enabled products, such as smartphones, tablets, C-V2X devices, and CPEs. 5G chipset by component has been segmented into baseband processor/modem and radio frequency integrated circuit (RFIC). RFIC has been further segmented into RF transceiver and RFF front end. Companies such as Qualcomm provides modem-to-antenna solutions like the snapdragon X55 5G mode, with its 5G mmWave antenna module (QTM525) and 5G mmWave chipsets SDX50M and QTM052. Other companies such as Analog Devices and MediaTek provide a 5G system on chip (SoC), and Samsung provides 5G RFICs and digital/along front-end (DFE) ASICs which support 28 GHz and 39 GHz bands.
Even start-up ecosystem has been growing rapidly in this market. Recently, Sivers Semiconductors has announced an acquisition of start-up company MixComm in a transaction worth $135 million. The move represents an investment by Sweden-based Sivers into the market for 5G in mmWave spectrum bands.
KEY ANALYTICAL HIGHLIGHTS
- 5G mmWave Baseband Processors are expected to have an installed base of 3.8 billion by 2026, mainly driven by mobile devices. 24 GHz to 39 GHz frequency band will account for the largest market of 5G mmWave chipset with more than 90% market share by 2026.
- RF Transceivers and RF FE are likely to reach $10.4 Billion and $23.5 Billion TAM respectively within 5G mmWave RFIC market by 2026.
- 138 thousand small cells are expected to be deployed by 2021 which is expected to rise to 3.25 million by 2026 considering dense small cell deployment by operators for mmWave. FWA is expected to be a major contributor to 5G mmWave infrastructure market as it was the first 5G use case. Apart this, 5.1 million CPEs are expected to be deployed by 2026.
- 5G mmWave macro cell market is expected to reach $4.8 billion by 2026. North America is the major contributor for Macro cells with ~83% share in 2021 as major 5G mmWave deployments are taking place in the US.
- In 5G network, the NFV will play a significant role in terms of providing operators the flexibility to expand their network functionality as well as provide effective and efficient operation of the network. NFV will enable network slicing and distributed cloud, which would supplement it to create flexible and programmable networks with an opportunity worth $3.1 billion
- 202 million devices with 5G mmWave support are expected to be shipped in 2021 and is likely to reach 1.1 billion units by 2026. Smartphone segment is expected to contribute major share of this market. A new application may emerge in the form of Robots and Drone contributing more than $110M for 5G mmWave by 2026
- The cost per square metre of a midband-only indoor 5G network versus a mmWave plus mid-band 5G network, assuming 10% of smartphones, laptops and security cameras are on 5G and 20% of both laptops and communications equipment are concurrently active. The result shows that if standard communications equipment is deployed, the yearly cost per square metre of a mid-band indoor network would amount to $2.86, while if advanced communications equipment is deployed, the cost per square metre of a mmWave plus mid-band network would amount to approximately $2.99.
CASE STUDIES ANALYZED
- Industrial
- Airbus partnered with Ericsson to increase aircraft production with 5G mmWave private network
- Nokia and WEG Brazil launch Industry 4.0 project with 5G standalone private wireless
- Fujitsu launched of a private 5G network at its Oyama plant in Tochigi Prefecture, Japan
- Verizon Business deployed 5G Ultra-Wideband indoors at General Motors and Honeywell
Defense
- GBL Systems and Samsung to deploy 5G Testbeds for AR/VR at U.S. Army military bases
- JMA Wireless demonstrated 5G private network that will launch a smart warehouse at the Marine Corps Logistics Base at Albany
Education
- Siklu deployed a multi-gigabit 5G network at Bar-Ilan University Smart City Center, Israel
- AT&T is deploying private 5G mmWave network at University of Connecticut’s (UConn) Stamford campus
- University of Missouri and AT&T collaborate to bring full 5G+ millimeter wave capability to MU’s campus.
Airports
- AT&T deployed 5G mmWave at Tampa International Airport
- SK Telecom installed 5G mmWave base stations at Incheon International Airport
Stadiums
- AT&T launches 5G mmWave at Seattle’s Football Stadium
- Verizon launches 5G mmWave in Tampa and at Raymond James Stadium
- Rakuten held trials of smart stadium using 5G mmWave network
Automobile
- Movandi demonstrated 5G MmWave Connectivity For Cellular Vehicle-To-Everything Communications
- Ericsson used advanced 5G technology to track a connected car
Transportation
- ADVA demonstrated Europe’s first 5G mmWave rail deployment
- Telia, Ericsson and Intel Corporation deliver 5G connectivity to Tallink’s cruise ships at the Port of Tallinn in Estonia
- DOCOMO achieves 5G communication between high-speed bullet train and experimental base stations using mmWave band
Public Safety
- AT&T offers 5G mmWave to first responders
Healthcare
- AT&T deploys private 5G network at Lawrence J. Ellison Institute for Transformative Medicine of USC
Key Questions to be answered through this study
- What are the major trends and drivers impacting 5G mmWave Chipset Market?
- What is the total cost of ownership and what are the cost implication of 5G small cells deployment?
- What is the revenue outlook (TAM) and forecast till 2026 for 5G mmWave Chipset Market by, Components (Baseband Processors, RFIC), Frequency (24-39 GHz, 40-57 GHz, Above 57 GHz), 5G Devices (Smartphones, Laptops, Tablets, Mobile Hubs, Robots, AR/VR Devices, Wearables, Drones, IoT Gateways, Surveillance Cameras) and Countries?
- How 5G mmWave Chipset market is expanding in other use-cases like Transportation, Public Safety, Education, Stadium, Airports, Défense, Industrial, Healthcare etc.?
- What is the competitive landscape of 5G mmWave Chipset Market?
- What is the strategic imperative and calls to action that will define growth and success within 5G mmWave Chipset by 2026?
Table of Contents
1 Introduction
1.1 5G Overview
1.2 5G Roadmap
1.3 5G spectrum bands
1.4 Role of mmWave in 5G
1.5 Comparison of 5G with other Connectivity Technologies
1.5.1 5G vs 4G
1.5.2 Wi-Fi 6 & 5G for private networks
1.5.3 Sub-6GHz vs mmWave
2 Executive Summary
3 Drivers & Opportunities
3.1 5G mmWave Capacity & Coverage
3.2 Higher densification
3.3 Larger Bandwidth
3.4 Larger Antenna Array in Small Form Factor
3.5 Channel Reciprocity
4 Cost implications of 5G small cell deployment
4.1 Large dense city
4.2 Small less dense city
5 5G mmWave Ecosystem
5.1 Device
5.2 Equipment
5.3 Communication Service Providers
5.4 Key Industry insights
6 Total Cost of Ownership Analysis
6.1 Dense urban
6.2 Fixed wireless access
6.3 Indoor
7 5G mmWave Deployment Options
7.1 Fixed Wireless Access
7.2 Indoor & Outdoor Small Cell Access
7.3 Integrated Access & Backhaul Small Cells
8 Regulatory Framework
8.1 US
8.1.1 Spectrum
8.1.2 Infrastructure
8.2 European Union
8.2.1 Spectrum
8.2.2 Infrastructure
8.3 Japan
8.4 South Korea
9 5G mmWave Case Studies
9.1 Industrial
9.1.1 Airbus partnered with Ericsson to increase aircraft production with 5G mmWave private network
9.1.2 Nokia and WEG Brazil launch Industry 4.0 project with 5G standalone private wireless
9.1.3 Fujitsu launched of a private 5G network at its Oyama plant in Tochigi Prefecture, Japan
9.1.4 Verizon Business deployed 5G Ultra-Wideband indoors at General Motors and Honeywell
9.2 Defense
9.2.1 GBL Systems and Samsung to deploy 5G Testbeds for AR/VR at U.S. Army military bases
9.2.2 JMA Wireless demonstrated 5G private network that will launch a smart warehouse at the Marine Corps Logistics Base at Albany
9.3 Education
9.3.1 Siklu deployed a multi-gigabit 5G network at Bar-Ilan University Smart City Center, Israel
9.3.2 AT&T is deploying private 5G mmWave network at University of Connecticut’s (UConn) Stamford campus
9.3.3 University of Missouri and AT&T collaborate to bring full 5G+ millimeter wave capability to MU’s campus.
9.4 Airports
9.4.1 AT&T deployed 5G mmWave at Tampa International Airport
9.4.2 SK Telecom installed 5G mmWave base stations at Incheon International Airport
9.5 Stadiums
9.5.1 AT&T launches 5G mmWave at Seattle’s Football Stadium
9.5.2 Verizon launches 5G mmWave in Tampa and at Raymond James Stadium
9.5.3 Rakuten held trials of smart stadium using 5G mmWave network
9.6 Automobile
9.6.1 Movandi demonstrated 5G MmWave Connectivity for Cellular Vehicle-To-Everything Communications
9.6.2 Ericsson used advanced 5G technology to track a connected car
9.7 Transportation
9.7.1 ADVA demonstrated Europe’s first 5G mmWave rail deployment
9.7.2 Telia, Ericsson and Intel Corporation deliver 5G connectivity to Tallink’s cruise ships at the Port of Tallinn in Estonia
9.7.3 DOCOMO achieves 5G communication between high-speed bullet train and experimental base stations using mmWave band
9.8 Public Safety
9.8.1 AT&T offers 5G mmWave to first responders
9.9 Healthcare
9.9.1 AT&T deploys private 5G network at Lawrence J. Ellison Institute for Transformative Medicine of USC
10 mmWave 5G Chipset Market Size & Forecast, By Frequency
10.1 24 GHz to 39 GHz
10.2 40 GHz to 57 GHz
10.3 Above 57 GHz
11 mmWave 5G Chipset Market Size & Forecast, By Component
11.1 Baseband Processor/Modem
11.2 RFIC
11.2.1 RF Transceiver
11.2.2 RF FE
12 Market Size, Shipment & Forecast, By Device
12.1 Mobile Devices
12.1.1 Smartphones
12.1.2 Laptops & Tablets
12.1.3 Mobile Hubs
12.1.4 Robots
12.1.5 Wearables
12.1.6 AR/VR
12.2 Non-mobile Devices
12.2.1 IoT Gateways
12.2.2 Surveillance cameras
12.3 Automobile
12.4 Telecommunication Infrastructure
12.4.1 Macro Cell
12.4.2 Small Cell
12.4.3 CPE
13 Regional Market Analysis & Forecast
13.1 Regional Impact of 5G mmWave Spectrum
13.2 mmWave Contribution To GDP
13.3 North America
13.4 Europe
13.5 Asia-Pacific
13.6 Rest of the World
13.6.1 Middle East & North Africa
13.6.2 Sub-Saharan Africa
13.6.3 Others
14 Competitive Landscape
14.1 Value Chain Analysis
14.2 mmWave 5G Chipset Market Share Analysis
15 Company Profiles
15.1 Qualcomm, Inc.
15.1.1 Overview
15.1.2 Solutions offered
15.1.3 Key developments
15.2 Samsung
15.2.1 Overview
15.2.2 Solutions offered
15.2.3 Key developments
15.3 Huawei
15.3.1 Overview
15.3.2 Solutions offered
15.3.3 Key developments
15.4 Nokia
15.4.1 Overview
15.4.2 Solutions offered
15.4.3 Key developments
15.5 MediaTek
15.5.1 Overview
15.5.2 Solutions offered
15.5.3 Key developments
15.6 Intel Corporation
15.6.1 Overview
15.6.2 Solutions offered
15.6.3 Key developments
15.7 Qorvo, Inc. (US),
15.7.1 Overview
15.7.2 Solutions offered
15.7.3 Key developments
15.8 Xilinx
15.8.1 Overview
15.8.2 Solutions offered
15.8.3 Key developments
15.9 Analog Devices
15.9.1 Overview
15.9.2 Solutions offered
15.9.3 Key developments
15.10 NXP Semiconductors
15.10.1 Overview
15.10.2 Solutions offered
15.10.3 Key developments
15.11 Marvell
15.11.1 Overview
15.11.2 Solutions offered
15.11.3 Key developments
15.12 Renesas
15.12.1 Overview
15.12.2 Solutions offered
15.12.3 Key developments
15.13 Anokiwave
15.13.1 Overview
15.13.2 Solutions offered
15.13.3 Key developments
15.14 MACOM
15.14.1 Overview
15.14.2 Solutions offered
15.14.3 Key developments
15.15 MaxLinear
15.15.1 Overview
15.15.2 Solutions offered
15.15.3 Key developments
15.16 MixComm
15.16.1 Overview
15.16.2 Solutions offered
15.16.3 Key developments
15.17 Sivers Semiconductor
15.17.1 Overview
15.17.2 Solutions offered
15.17.3 Key developments
15.18 Movandi
15.18.1 Overview
15.18.2 Solutions offered
15.18.3 Key developments
15.19 Peraso
15.19.1 Overview
15.19.2 Solutions offered
15.19.3 Key developments
15.20 SIMCom Wireless Solutions
15.20.1 Overview
15.20.2 Solutions offered
15.21 Quectel
15.21.1 Overview
15.21.2 Solutions offered
15.21.3 Key developments
15.22 Mobix Labs
15.22.1 Overview
15.22.2 Solutions offered
15.22.3 Key developments
15.23 Microamp Solutions
15.23.1 Overview
15.23.2 Solutions offered
Companies Mentioned (Partial List)
A selection of companies mentioned in this report includes, but is not limited to:
- Analog Devices
- Anokiwave
- Huawei
- Intel Corporation
- MACOM
- Marvell
- MaxLinear
- MediaTek
- Microamp Solutions
- MixComm
- Mobix Labs
- Movandi
- Nokia
- NXP Semiconductors
- Peraso
- Qorvo, Inc. (US),
- Qualcomm
- Quectel
- Renesas
- Samsung
- SIMCom Wireless Solutions
- Sivers Semiconductor
- Xilinx