3D sensing – and more – in smartphones will drive the VCSEL market for the next five years
KEY FEATURES OF THE REPORT
- VCSEL market revenue and volume: 2017-2023
- Detailed technical and market analysis of VCSEL applications, with in-depth analysis of the consumer and automotive landscapes
- VCSEL industry analysis: from epiwafer to system
- VCSEL specifications and price analysis
- VCSEL manufacturing analysis
- VCSEL IP analysis
OBJECTIVES OF THE REPORT
This report’s objectives are to:
- Give a comprehensive picture of the forces driving the VCSEL light source market, technology and industry in the short, middle and long term
- Allow readers to understand the global landscape related to VCSELs
- Review main applications of VCSELs, giving insights on principles, technology, technical requirements, trends, key players and more
- Analyse the technology and industry behind VCSEL light sources and their integration into sensors and modules
- Provide and analyze market forecasts for VCSEL light sources from 2017 – 2023
- Present an Intellectual Property (IP) analysis in order for the reader to better understand the patent landscape related to VCSEL device, system and applications
Table of contents
Preliminary Definitions and Principles 33
VCSEL Overview 39
- Applications as a function of the electromagnetic spectrum
VCSEL in the semiconductor light source environment
- History of VCSELs
- VCSEL structure
- VCSELs in the electromagnetic spectrum
- Timeline of main applications for VCSELs
VCSEL Landscape 51
- Classification of VCSEL applications by wavelength
- Classification of VCSEL applications by market segment
- Classification of VCSEL applications by function
VCSEL Market 59
- 2017-2023 market volume (Munits) – By application
- 2017-2023 market revenue ($M) – By application
- 2017-2023 growth trends by application
- Market growth relays
- VCSEL ASP
- MOCVD reactor opportunity
VCSEL Applications 75
- Active optical cable
- Plastic Optical Fibre (POF) in automotive
- Laser printer
- Industrial heating system
- Proximity sensors
- Autofocus systems
- Gas sensors
- Computer mice
- Pulse oximeters
- Surveillance cameras
- Eye tracking systems
- Face recognition
- Gesture recognition
- Optical Coherence Tomography (OCT)
VCSEL Manufacturing 123
- VCSEL vs EEL
- Basic properties of VCSELs
- VCSEL specifications vs. Application requirements
- Epitaxy – Technologies and trends
- Key front-end process steps
- Reliability aspects
- The case of array manufacturing
- Front-end manufacturing control
VCSEL Industry 153
- Key players
- Consumer and mobile landscape
- Automotive landscape
VCSEL Intellectual Property Landscape 207
- Patent segmentation
AFTER 20 YEARS, THE VCSEL BUSINESS HAS FOUND ITS KILLER APPLICATION – AND IS LIKELY TO EXPLODE
Data communications (datacoms) was the first industrial application to start integrating Vertical Cavity Surface Emitting Lasers (VCSELs). Their sweet spot has been in short-distance data communication due to their low power consumption and competitive price compared to Edge Emitting Lasers (EELs). Driven by the development of datacenters, the VCSEL market and production boomed in the 2000s with the internet’s popularity, and then grew steadily. Some new applications for VCSEL emerged, like laser printers and optical mice, but weren’t strong growth drivers.
Only in 2014, almost 20 years since the first use of the technology in datacom, VCSELs started to make their way into high volume consumer smartphones. But this coupling with sensors for proximity sensing and autofocus functions was only the beginning of the VCSEL success story. In 2017 Apple released the iPhone X, with a 3D sensing function based on this technology. The iPhone X integrates three different VCSEL dies for the proximity sensor and the Face ID module, and made the VCSEL market explode in 2017, propelling overall revenue to ~$330M.
Good iPhone X sales have now triggered the interest of other smartphone brands in this breakthrough 3D sensing function. Less than one year after the release of Apple’s flagship, its competitors are now following the same trend and starting to integrate 3D sensing technologies. Xiaomi and Oppo were the quickest on the draw, with the Xiaomi Mi8 and the Oppo Find X models presented in the second quarter of 2018. Other leading smartphone players like Huawei, Vivo or Samsung are also expected to integrate VCSELs into their flagship models by 2019. In this context, the explosion of VCSEL demand initiated in 2017 will persist for the next five years, potentially multiplying the business opportunity more than tenfold. During that time, the technology might also find some new growth drivers into some other high volume applications such as automotive Light Detection and Ranging (LiDAR) or gas sensors.
This trend will likely cause rapid evolution in the VCSEL industry in coming years in the form of investment, new entrants and mergers and acquisitions (M&A).
NOT ALL VCSELS ARE CREATED EQUAL! APPLICATIONS DRIVE DEVICE SPECIFICATIONS
The variety of applications using VCSELs involves a variety of specifications at the device level, mostly in size, output power and number of laser cavities. As a result, the surface of a VCSEL chip or array can range from less than 0.1mm² for datacom and proximity sensing applications to more than 70mm² for LiDAR application. As the VCSEL surface increases with the needed output power,so do the number of cavities and the complexity of the manufacturing process, mostly in ‘front-end’ chip fabrication.
The current shift from the datacom industrial era to the 3D sensing consumer era is likely to have a strong impact on manufacturing expertise related to VCSELs. Typically, whereas datacom uses 3” or 4” diameter wafer manufacturing processes, consumer applications requires 6” wafer processing to hit their cost targets and also larger VCSEL arrays. This evolution has a direct impact on manufacturing yield, which is still low today for 6” processes. This is mostly related to epiwafer manufacturing, for which the epitaxy uniformity is still a major challenge, compared to 3” or 4” wafer epitaxy. Typically, a difference of 1% in the layer thickness will result in a wavelength deviation of 10nm. And knowing that epitaxy yield will drive overall VCSEL manufacturing yield, it is now at the heart of VCSEL industry investments in key equipment for MOCVD and metrology.
This report present a detailed analysis of VCSEL manufacturing processes, associated challenges, recent trends and player positioning. This report also presents main specifications for VCSELs in leading applications.
A NEW WAVE OF INVESTMENT AND M&A HAS STARTED
VCSEL market volume is expected to grow from 652M units in 2017 to more than 3.3B units in 2023 at a 31% compound annual growth rate for this period (CAGR2017-2023). This booming trend is likely to trigger interest in VCSEL technology at many industry levels, including OEMs, integrators, device manufacturers, epi houses, foundries, equipment and material suppliers. To be able to follow this booming demand, more than 100 MOCVD reactors will be needed, which is likely to please companies that supply this equipment, such as Aixtron, Veeco and Taiyo Nippon Sanso.
Yole Développement (Yole) expects therefore strong investment and proliferation in the VCSEL industry with the entry of several new players, mostly from the LED industry, whose technology is similar. Since 2016, Yole analysts’ have already seen some M&A, like ams’ acquisition of Princeton Optronics and Osram’s deal for Vixar and investment in manufacturing expansion or supply chain reinforcement, like Apple investing $390M in Finisar. Yole expects the bulk of these investments to occur in the coming years.
And once VCSEL hype reaches its peak, Yole also expects a necessary consolidation phase with more M&A occurring at all level of the supply chain and to support different strategies:
- Vertical integration – from system to module and/or from module to component
- Application diversification – from datacom to sensing
- Business diversification – from LED or EEL devices to VCSELs
This report presents an in-depth analysis of the VCSEL industry, which highlights supply chain trends and key players. The reports also analyze VCSEL device market size, broken down by application and segment, and the related MOCVD reactor market. In addition, it details an overview of the VCSEL IP landscape.
Accelink, Aixtron, Alight, ams, Anadigics, Apple, Arima Lasers Corporation, Asus, Audi, Avago, AWSC, Beam Express, Blackmore, Bosch, Broadcom, Cable solutions, Canon, Changelight, Continental, Device Innovation, Egismos Technology Corporation, Emcore, Epistar, Epiworks, Excelitas, Finetech, Finisar, FLIR, Foxconn, Fuji Xerox, Fujitsu, Global Communication Semiconductor, Google, Hamamatsu, Hella, Heptagon, Himax, HLJ, Honeywell, Honor, HTC, Huawei, Ibeo, iHealth, II-VI, Infineon, Infinera, Inneos, Innoluce, Innoviz, Intel, IntelliEpi, IQE, JDSU, Journal of semiconductors, Kaiam, Koito, Landmark Opto, Lasermate, Lasertel, Laytec, LeddarTech, Lenovo, LG, Lumentum, Luminar, Luxnet, Magneti Marelli, Mantis Vision, Masimo, Namuga, Oclaro, Oculus, Omnivision, OnePlus, Oppo, Optek Technology, Optical Society of America, Optovue, Optowell, Orbbec, Osram, Oxford Instruments, Palomar Technologies, Philips Photonics, Picolight, pmd, POET Technologies, Primesense, Princeton Optronics, QSI, Quanergy, Rasirc, Raycan, Realsense, Riber, Ricoh, Robosense, Samsung, Sanan, Santec Corporation, SCAT, Seiko Epson, Seminex, SensL, Shiraz University, Sick, SinoSemic, SoftKinetic, Sony Corporation, Stanley, STMicroelectronics, Sumitomo Chemicals, Sunny optical technology, Suoer, Taiyo Nippon Sanso, Tetravue, Texas Advanced Optoelectronic Solutions, Thorlabs, Trilumina, Truelight Corporation, Tyson Technology, Ulm Photonics, Ultra Communication, US Lasers Inc., Ushio, Valeo, Varroc, Veeco, Velodyne, Vertically Integrated Systems, Vertilas, Vertilite, Viavi, Vivo, Vixar, VPEC, Wavetek, Win Semiconductor, Xiaomi, Zephyr Photonics, ZF (…)
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