Category Archives: Displays

Javier Vela, scientist at the U.S. Department of Energy’s Ames Laboratory, believes improvements in computer processors, TV displays and solar cells will come from scientific advancements in the synthesis of low-dimensional nanomaterials.

Ames Laboratory scientists are known for their expertise in the synthesis and manufacturing of materials of different types, according to Vela, who is also an Iowa State University associate professor of chemistry. In many instances, those new materials are made in bulk form, which means micrometers to centimeters in size. Vela’s group is working with tiny, nanometer, or one billionth of a meter sized, nanocrystals.

“We’re trying to find out what happens with materials when we go to lower particle sizes, will the materials be enhanced or negatively impacted, or will we find properties that weren’t expected,” Vela said. “Our goal is to broaden the science of low-dimensional nanomaterials.” In an invited paper published in Chemistry of Materials entitled, “Synthetic Development of Low Dimensional Materials”, Vela and coauthors Long Men, Miles White, Himashi Andaraarachchi, and Bryan Rosales discussed highlights of some of their most recent work on the synthesis of low dimensional materials.

One of those topics was advancements in the synthesis of germanium-based core-shell nanocrystals. Vela says industry is very interested in semiconducting nanocrystal-based technologies for applications such as solar cells.

Small particle size can affect many things from transport properties (how well a nanocrystal conducts heat and electricity) to optical properties (how strong it interacts with light, absorbs light and emits light). This is especially true in photovoltaic solar cells “Let’s say you’re using a semiconductor material to make a solar device, there’s often different performance when solar cells are made from bulk materials as opposed to when they are made with nanomaterials. Nanomaterials interact with light differently; they absorb it better. That’s one way you can manipulate devices and fine tune their performance or power conversion efficiency,” said Vela.

Beyond solar cells, Vela says there’s tremendous interest in using nanocrystals in quantum dot television and computer displays, optical devices like LEDs (light-emitting diodes), biological imaging, and telecommunications.

He says there are many challenges in this area because depending upon the quality of the nanocrystals used, you can see different emission properties, which can affect the purity of light. “Ultimately the size of the nanocrystals being used can make a huge difference in the cleanliness or crispness of colors in TV and computer displays,” said Vela. “Television and computer technology is a multibillion dollar business worldwide, so you can see the potential value our understanding of properties of nanocrystals could bring to these technologies.”

In the paper, Vela’s group also discussed advancements made in the study of synthesis and spectroscopic characterization of organolead halide perovskites, which Vela says are some of the most promising semiconductors for solar cells because of their low cost and easier processability. He adds photovoltaics made of these materials now reach power conversion efficiencies of greater than 22 percent. Vela’s research in this area has focused on mixed-halide perovskites. He says his group has discovered these materials exhibit interesting chemical and photo physical properties that people hadn’t realized before, and now they are trying to better understand the correlation between the structure and chemical composition of perovskites and how they behave in solar cells. “One of our goals is to use what we’ve learned to help lower the cost of solar cells and produce them more reliably and readily,” Vela said.

In addition, Vela’s group is studying how to replace lead in traditional organolead halide perovskites with something less toxic, like germanium. “In principle, this is an area that should be much better known, but it’s not,” said Vela. “When we’ve been able to substitute germanium for lead, we have been able to produce a lighter perovskite, which he says could positively impact the automotive industry, for example.

“This could have great implications for transportation applications where you don’t want a lot of lead because it’s so heavy,” said Vela. Going forward Vela says his group’s focus will be on advancing the science in low-dimensional materials.

“We’re not working with well-known materials, but the newest; the most recently discovered,” Vela said. “And every time we can advance the science we’re one step closer to opportunities for more commercialization, more production, more manufacturing and more jobs in the U.S.”

With consumers already accustomed with using smartphones and tablet PCs in their everyday lives, touch screens are now increasingly making their way into their vehicles, too. Automotive touch panel shipments are expected to top 50 million units in 2017, up 11 percent from 45 million units in 2016, according to IHS Markit (Nasdaq: INFO). More importantly, capacitive-touch screen shipments are forecast to surpass that of traditionally-dominated resistive-touch screens in vehicles in 2017.

“Projected capacitive-touch technology is commonly found in consumer smartphones and tablet PCs, which consumers have grown very comfortable using,” said Shoko Oi, senior display analyst at IHS Markit. “Although there are safety concerns about operating touch screens while driving, automotive touch panels are becoming a standard feature in new vehicles entering the market.”

Automotive screens now display content from a variety of sources coming from both inside and outside the car. However, many newer applications now require touch screen panels, which shifts the role of in-car displays from simply revealing information visually to becoming an actual human-machine interface. This shift, along with the increased volume of displayed data, is driving a growing need for easy-to-see designs of displays that incorporate larger sizes, non-rectangular or curved shapes, as well as higher resolutions.

170530_automotive_touch_panel

According to the IHS Markit Automotive Touch Panel Market Report, as vehicle models are updated, projected capacitive-touch technology is replacing resistive-touch technology as the mainstream touch solution for automotive displays despite the higher module costs.

“The latest trends towards connected cars and telematics are prompting more car manufacturers to consider the adoption of projected capacitive-touch screens that can provide a similar user experience found in touch displays of smartphones and tablet-PCs,” Oi said.

By Ayo Kajopaiye, Collaborative Technology Platforms, SEMI

What does Smart Manufacturing mean for the future of the electronics manufacturing supply chain?  SEMI members hold many different perspectives, but one thing is clear ─ the impact of Smart Manufacturing will be huge. SEMI is fully involved with many of the activities that center on Smart Manufacturing.

During the North America Standards meetings that took place at SEMI’s new Headquarters in February, the Automation Technology Committee Chapter in Taiwan was successfully chartered.  K.C. Chou, co-chair of the new Committee, believes in SEMI’s role, saying, “SEMI has a strong reputation for successful standardization which is why the Taiwan PCB industry has selected the global SEMI Standards platform to develop consensus on equipment communication and other manufacturing areas where standards are needed to drive down cost.”

What does the formation of this Committee mean for Smart Manufacturing in the PCB industry? “The industry can now use the Committee to drive consensus on how to adopt GEM technology so it can be implemented consistently” says Brian Rubow, director of Client Training and Support at Cimetrix. “Without these standards agreed upon, every equipment that needs to be integrated may have to have different technology adopted, making the process more difficult just to create a line that will produce their product since a lot of custom integration has to be done. However, once a standard is adopted, instead of spending time dealing with protocols, communication methods and messaging scenarios, they will be able to be a lot more productive and focus on building products and not worry about integrated equipment” he continues.

Next steps

The next step for the new Committee is to propose a ballot for distribution that will address adoption of GEM technology. “Anyone who is interested in this technology, now is the best time to get involved and get their ideas into the collaboration,” Rubow adds. He expects the balloting process to begin over the next quarter.

Many other Smart Manufacturing Programs

SEMI also has a Smart Manufacturing Initiative that is being led by a group of industry leaders through the SEMI Smart Manufacturing Advisory Council. This Council works closely with the Smart Manufacturing Special Interest Group which consists of a broader group of members across different regions as they focus on facilitating collective efforts on issues related to smart manufacturing. Also, members that are part of this group are connected to information and resources that can help with the implementation, supply, services or research of smart manufacturing systems. SEMI plans to continue to play an essential role in the emergence of Smart Manufacturing in the electronics industry.

For questions regarding the Smart Manufacturing Special Interest Group and Advisory Council please contact Tom Salmon, VP of Collaborative Technology Platforms – [email protected] or 408-943-6965.

Also be sure to take a look at SEMI’s Smart Manufacturing Central webpage for information related to Smart Manufacturing – www.semi.org/en/smart-manufacturing-central

SEMICON West 2017

Smart Manufacturing topics (Manufacturing, Automotive, and MedTech) will be covered at SEMICON West 2017. Under the “Programs” tab at the top, visit the “Agenda at a Glance” (filter listings to Smart Topics).  Learn more and register now.

Other SEMI shows will also feature Smart Manufacturing topics, including SEMICON Taiwan (September 13-15 in Taipei), SEMICON Europa (November 14-17 in Munich), and SEMICON Japan (December 13-15 in Tokyo).

UPV/EHU-University of the Basque Country’s researchers have explored superelasticity properties on a nanometric scale based on shearing an alloy’s pillars down to nanometric size. In the article published by the prestigious scientific journal Nature Nanotechnology, the researchers have found that below one micron in diameter the material behaves differently and requires much higher stress for it to be deformed. This superelastic behaviour is opening up new channels in the application of microsystems involving flexible electronics and microsystems that can be implanted into the human body.

Superelasticity is a physical property by which it is possible to deform a material to a considerable extent, up to 10%, which is much higher than that of elasticity. So when stress is applied to a straight rod, the rod can form a U-shape and when the stress applied is removed, the rod fully regains its original shape. Although this has been amply proven in macroscopic materials, “until now no one had been able to explore these superelasticity properties in micrometric and nanometric sizes,” explained José María San Juan, lead researcher of the article published by Nature Nanotechnology and a UPV/EHU professor.

Researchers in the UPV/EHU’s Department of Condensed Matter Physics and Applied Physics II have managed to see that “the superelastic effect is maintained in really small devices in a copper-aluminium-nickel alloy”. It is an alloy with shape memory on which the research team has been working for over 20 years on a macroscopic level: Cu-14Al-4Ni, an alloy that displays superelasticity in ambient temperature.

Pillars were built using the Cu-Al-Ni alloy, each one with a diameter measuring about 500 nm (half a micrometre). Credit: José María San Juan / UPV/EHU

Pillars were built using the Cu-Al-Ni alloy, each one with a diameter measuring about 500 nm (half a micrometre). Credit: José María San Juan / UPV/EHU

By using a piece of equipment known as a Focused Ion Beam, “an ion cannon that acts as a kind of atomic knife that shears the material”, explained San Juan, they built micropillars and nanopillars of this alloy with diameters ranging between 2 μm and 260 nm –a micrometre is one millionth of a metre and a nanometre one thousand-millionth of a metre–. And to them they applied a stress using a sophisticated instrument known as a nanoindenter, which “allows extremely small forces to be applied,” and then they measured their behaviour.

The researchers have for the first time confirmed and quantified that in diameters of less than a micrometre there is a considerable change in the properties relating to the critical stress for superelasticity. “The material starts to behave differently and needs a much higher stress for this to take place. The alloy continues to display superelasticity but for much higher stresses”. San Juan highlights the novelty of this increase in critical stress linked to size, and also stresses that they have been able to explain the reason for this change in behaviour: “We have proposed an atomic model that allows one to understand why and how the atomic structure of these pillars changes when a stress is applied”.

Microsystems involving flexible electronics and devices that can be implanted in the human body

The UPV/EHU professor highlighted the importance of this discovery, “spectacular superelastic behaviour on a small scale”, which opens up new channels in the design of strategies for applying alloys with shape memory to develop flexible microsystems and electromechanical nanosystems. “Flexible electronics is very much present on today’s market, it is being increasingly used in garments, sports footwear, in various displays, etc.” He also affirmed that all this is of crucial importance in developing smart healthcare devices of the Lab-on-a-chip type that can be implanted into the human body. “It will be possible to build tiny micropumps or microactuators that can be implanted on a chip, and which will allow a substance to be released and regulated inside the human body for a range of medical treatments.”

It is a discovery that “is expected to have great scientific and technological repercussions and offer the potential to revolutionise various aspects in related fields,” concluded San Juan, and he welcomed the fact that “we have managed to transfer all the necessary knowledge and to acquire the working tools that the most advanced centres can avail themselves of to open up a new line of research which can be fully developed at the UPV/EHU”.

As panel makers are increasingly targeting the premium TV market, active-matrix organic light-emitting diode (AMOLED) TV panel shipments are expected to exceed 10 million units by 2023, growing at a compound annual growth rate (CAGR) of 42 percent from 2017, according to IHS Markit (Nasdaq: INFO).

Panel manufacturers are continuously increasing AMOLED TV panel line-up with differentiated picture quality and figure, targeting the premium TV market. However, high manufacturing cost of the AMOLED TV panel will remain a hurdle to its shipment increase, according to IHS Markit analysis.

“LG Display is the only AMOLED TV panel supplier continuously increasing ultra-high definition (UHD) AMOLED TV panel shipments, while planning to discontinue the mass production of full HD AMOLED TV panel in 2017,” said Jerry Kang, principal analyst of display research at IHS Markit.

“This indicates most TV brands recognize that AMOLED TV will be more competitive in the premium TV market, which is less price-sensitive than even the high-end TV market, considering the relatively high manufacturing cost of AMOLED TV panels.” The 65-inch UHD TV panel will account for 48 percent of the total AMOLED TV panel shipments in 2017.

Figure 1

Figure 1

According to the IHS Markit Large Sized AMOLED Technology & Market report, most of AMOLED panel manufacturers are trying to develop an ink-jet AMOLED process, seen as a viable way to reduce manufacturing costs. However, they are facing challenges with the soluble emitting materials used in the process, resulting in low-performance yields.

“The panel manufactures are now associating themselves with a few equipment and material suppliers to develop and optimize the ink-jet AMOLED process, with an aim to mass produce AMOLED TV panels utilizing essentially an ink-jet printer by 2019,” Kang said.

The IHS Markit Large Sized AMOLED Technology & Market report covers the latest market trend and the forecast of AMOLED displays of 9.7 inches and larger, technologies analysis and panel makers’ strategies by region.

Air Products (NYSE: APD), an industrial gases company, today announced it has recently received multiple, long-term supply awards from semiconductor and flat panel display manufacturers in China as the country’s electronics manufacturing industry continues to boom.

Industrial gases supply contracts awarded to Air Products over the past 12 months call for the investment in six industrial gas plants and a pipeline network for the supply of gaseous nitrogen and oxygen, as well as other bulk gases. These facilities will support existing and new customers in key electronics clusters and industrial parks in China’s major economic regions, including the Yangtze River Delta in Eastern China, Pearl River Delta in Southern China, and BeijingTianjinHebei region in Northern China.

“We are greatly honored to be selected by our existing as well as new customers to support their growth plans in China. These wins speak volumes about their confidence in our capabilities,” said Saw Choon Seong, China president, Industrial Gases at Air Products. “Air Products has been serving the China market for 30 years. These recent strategic investments reflect our continued commitment to supporting the fast-paced development of electronics manufacturing customers here who are gaining new momentum for growth under the country’s 13th Five-Year Plan and ‘Made in China 2025′ initiative. We will continue to bring our scale, innovation, and reliable and safe supply to enable them to thrive.”

The Chinese Government has a strong commitment to boosting development of the electronics industry. One initiative is the establishment of the National Integrated Circuit Industry Investment Fund, commonly known as the Big Fund, to invest roughly USD 20 billion from 2014 through 2017 in the country’s semiconductor industry. In addition, local governments have also set up regional-level funds totalling around USD 100 billion to promote key technologies and major projects.

Air Products’ wins over the past 12 months include some landmark projects in China’s electronics industry, and some are state-level projects, such as:

  • A new memory fab in the Fujian (Jinjiang) Integrated Circuit Industrial Park in Fujian Province, Southern China; and
  • A new foundry in the Pukou Economic Development Zone (PKEDZ) in Eastern China, a state-level high-tech park which will be home to advanced manufacturing and is only 35 kilometers away from the Nanjing Chemical Industry Park (NCIP). Air Products has already built a leading position in the NCIP serving several hundred customers in the park and across Nanjing through pipelines and various supply modes.

Air Products has been an industrial gases supplier to the global electronics industry for over 40 years. In China, the company has been serving many world-leading and domestic manufacturers in the development of next generation electronics devices by leveraging its strong and reliable supply network across the country. One example is the supply to one of China’s most advanced fabs, which is located in Xian City, Western China, and is owned and operated by a leading global semiconductor company. Air Products is also supplying the country’s highest-generation, most advanced and most efficient TFT-LCD (thin-film transistor liquid crystal display) fab located in the Banan Jieshi IT Industrial Park in Chongqing City, Western China.

Currently, most parts of a smart phone are made of silicon and other compounds, which are expensive and break easily, but with almost 1.5 billion smart phones purchased worldwide last year, manufacturers are on the lookout for something more durable and less costly.

Dr. Elton Santos from Queen's University Belfast Credit: Queen's University Belfast

Dr. Elton Santos from Queen’s University Belfast
Credit: Queen’s University Belfast

Dr. Elton Santos from Queen’s University’s School of Mathematics and Physics, has been working with a team of top-notch scientists from Stanford University, University of California, California State University and the National Institute for Materials Science in Japan, to create new dynamic hybrid devices that are able to conduct electricity at unprecedented speeds and are light, durable and easy to manufacture in large scale semiconductor plants.

The team found that by combining semiconducting molecules C60 with layered materials, such as graphene and hBN, they could produce a unique material technology, which could revolutionise the concept of smart devices.

The winning combination works because hBN provides stability, electronic compatibility and isolation charge to graphene while C60 can transform sunlight into electricity. Any smart device made from this combination would benefit from the mix of unique features, which do not exist in materials naturally. This process, which is called van der Waals solids, allows compounds to be brought together and assembled in a pre-defined way.

Dr. Elton Santos explains: “Our findings show that this new ‘miracle material’ has similar physical properties to Silicon but it has improved chemical stability, lightness and flexibility, which could potentially be used in smart devices and would be much less likely to break.

“The material also could mean that devices use less energy than before because of the device architecture so could have improved battery life and less electric shocks.”

He added: “By bringing together scientists from across the globe with expertise in chemistry, physics and materials science we were able to work together and use simulations to predict how all of the materials could function when combined – and ultimately how these could work to help solve every day problems.

“This cutting-edge research is timely and a hot-topic involving key players in the field, which opens a clear international pathway to put Queen’s on the road-map of further outstanding investigations.”

The project initially started from the simulation side, where Dr. Santos predicted that such assembly of hBN, graphene and C60 could result in a solid with remarkable new physical and chemical properties. Then, he talked with his collaborators Professor Alex Zettl and Dr. Claudia Ojeda-Aristizabal at the University of California, and California St University in Long Beach (CA) about the findings. There was a strong synergy between theory and experiments throughout the project.

Dr. Santos said: “It is a sort of a ‘dream project’ for a theoretician since the accuracy achieved in the experiments remarkably matched what I predicted and this is not normally easy to find. The model made several assumptions that have proven to be completely right.”

The findings, which have been published in one of the most prestigious journals in the world ACS Nano, open the doors for further exploration of new materials. One issue that still needs to be solved with the team’s current research is that graphene and the new material architecture is lacking a ‘band gap’, which is the key to the on-off switching operations performed by electronic devices.

However, Dr. Santos’ team is already looking at a potential solution – transition metal dichalcogenides (TMDs). These are a hot topic at the moment as they are very chemically stable, have large sources for production and band gaps that rival Silicon.

He explains: “By using these findings, we have now produced a template but in future we hope to add an additional feature with TMDs. These are semiconductors, which by-pass the problem of the band gap, so we now have a real transistor on the horizon.”

FlexTech’s annual Flexible Electronics Conference and Exhibit – 2017FLEX – is set for the Hyatt Regency Hotel & Spa in Monterey, Calif.  from June 19-22, 2017. Consistently attracting 500+registrants, the event is the premier technology conference for the emerging flexible electronics industry. Twenty-six sessions will cover the landscape of flexible hybrid electronics and printed electronics, including R&D, manufacturing and applications. Short courses and networking events round out 2017FLEX.

According to Zion Research, “global demand for the flexible electronics market was valued at $5.13 billion in 2015 and is expected to generate revenue of $16.5 billion by 2021, growing at a CAGR of slightly above 21 percent between 2016 and 2021.”  Key elements of the market include flex displays, sensors, batteries, and memory. Applications also abound in the automotive, consumer electronics, healthcare, and industrial sectors.

While technology advancement and accelerating to manufacturing are the primary themes of the FLEX Conference, applications and business trends are highlighted on the opening day:

  • Applied Materials Keynote by Brian Shieh, corporate VP and GM, Display Business Group, on the flexible display market
  • Flex, the global EMS provider, and NextFlex, America’s Flexible Hybrid Electronics Manufacturing Institute, on the challenges and solutions for manufacturing flexible and stretchable electronics
  • Libelium on how new IOT platforms that integrate sensors to monitor and control body parameters will lead to better healthcare for billions
  • Experience Co-Creation Partnership on the ten starting points for the development of flexible/hybrid sensors for agriculture and food
  • NovaCentrix on the OE-A Roadmap 2017, giving an outlook on organic and printed electronics developments and prospects
  • Gartner Group on when flexible electronics will reach critical mass

Sessions are planned for FHE manufacturing, standards and reliability, substrates, conductors, inspection, encapsulation and coating, nanoparticle inks, direct write, and 3D printing, among others. Well-known companies will present, such as Molex, Panasonic, Eastman Chemical, and Northrup Grumman, as well as leading universities, and the U.S. Army and U.S. Air Force Research Laboratories.

Among the R&D organizations presenting at 2017FLEX are CEA-LITEN (France), ETRI (South Korea), Flexible Electronics & Display Center (USA), Fraunhofer Institute (Germany), Holst Center (Netherlands), National Research Council (Canada), PARC (USA), and VTT (Finland). Topics of the presentations range from new forms of flexible substrates to TFT and OLED pilot lines to printed health monitoring sensors.

The exhibit floor, short courses and networking opportunities round out the event, as well as many member-only meetings.  FlexTech, the Nano-Bio Manufacturing Consortium (NBMC) and NextFlex hold member and planning meetings for the governing councils, technical councils and technology working groups.  Initiatives in manufacturing, mobile power, e-health, as well as project proposals will be discussed, all buoyed by the information shared during the technical conference.

For more information on 2017FLEX, please visit:  www.semi.org/en/2017-flex

Today FlexTech, A SEMI Strategic Association Partner, announced the full agenda for the inaugural flexible hybrid electronics (FHE) conference coming up on May 31-June 1 in Seoul at COEX Exhibition Center.  The new conference, 2017FLEX Korea, focusing on the theme “A Practical Path to Flexible Hybrid Electronics,” is brought to action with a market-focused agenda and presentations on Displays, Wearables, Sensors, OLED, Quantum Dot, Micro LED, Head Up Display, Roll-to-Roll and 3D Printing by experts from both the industry and academia.

2017FLEX Korea features a technical conference, a Short Course, and networking opportunities. The two-day technical conference includes four sessions on critical areas for FHE success. The four sessions will feature 14 technology experts from Korea, America, Asia and Europe representing organizations active in the FHE area, including:

  • Display Applications: KIMM and UIN3D
  • Wearables and Sensors Applications: KT and KITECH
  • Emerging Markets Applications: EyeDis, KOPTI, and KITECH
  • Core Technology Applications: Coatema Coating Machinery GmbH, Daelim Chemical, Dankook University, DuPont, Kolon Industries, Nanosys, and Universal Display Corporation

Three keynotes will set the stage for all of the other topics, including:

  • LG Display: “Flexible Display Changes Your Life” by Joon Young Yang, head of OLED Advanced Research Division
  • FlexTech: “Emerging Product Opportunities and the Worldwide Ecosystem of FHE” by Melissa Grupen-Shemansky, Chief Technology Officer
  • Samsung Advanced Institute of Technology: “Quantum Dot Display” by Shinae Jun, research master

Combining traditional IC manufacturing with printed electronics, FHE is the leading technical approach to design and manufacture devices for fast-growth markets. Flexible and printed electronics applications have the potential to create business opportunities in growing market opportunities such as wearables, health care, flexible displays and other advanced applications. A 3-hour Short Course is intended for individuals and organizations seeking a comprehensive overview on the Printed Electronics industry.

“We are pleased to hold the 2017FLEX Korea conference,” said Hyun-Dae CHO, president of SEMI Korea. “We hope the conference will provide you with the insights into the FHE industry and you will also find networking opportunities at the event.”

Register by May 26 to reserve your spot with a discounted price: http://www.semi.org/ko/flex-korea-register

The primary automotive display systems market will reach $11.6 billion in tier one supplier revenue globally in 2017, according to new analysis from business information provider IHS Markit (Nasdaq: INFO).

The market is set to increase drastically over the next few years, says the latest Automotive Display Systems Forecasts from IHS Markit. The most valuable are the Center Stack Displays and Instrument Cluster Displays, representing global revenues of $6.1 and $4.8 billion respectively. Head-Up Displays (HUD) account for only $731 million today, but show the largest growth potential in terms of percentage going forward through 2022. In 2022, combined value from the Center Stack Display, Instrument Cluster Display and Head-Up Display system markets total more than $20.8 billion, an increase of $9.2 billion in annual revenue in just five years, according to IHS Markit.

“There are a few different sources of this increase in display value within the automotive sector,” said Brian Rhodes, automotive technology analyst for IHS Markit. “First are simple volume increases, with more vehicles adding new displays to the instrument cluster and center stack, along with Head-Up Display deployments becoming more common. The second area of growth is in the technology value itself, as these displays are becoming larger and more capable – and therefore more expensive.”

Continental leads display system suppliers

Continental is expected to be the top supplier of primary automotive display systems in 2017 based on global revenue forecasts, the IHS Markit research says. Visteon follows closely behind, as the only other supplier with a double-digit market share in this space. Panasonic, Denso and Bosch round out the remaining market share leaders in the top five. Combined, these suppliers account for more than $6 billion in revenue resulting from Center Stack Display, Instrument Cluster Display and Head-Up Display systems in 2017.

“The top five primary display system suppliers command more than half of the total automotive display systems market,” Rhodes said. “While this is certainly a large portion of revenue for a handful of large players, it still means there is an incredible amount of fragmentation left over offering opportunity for the rest of the supply base — both in today’s market and in the foreseeable future based on our forecasts.”

Safety information related display panels offer strong growth potential

Thin film transistor liquid crystal display (TFT LCD) automotive display panel market shipments are expected to grow from 135 million units in 2016 to 200 million units in 2022. This technology will represent more than 67 percent share of total automotive display shipments, according to the Automotive Display Market Tracker from IHS Markit.

“The market growth momentum has shifted from center stack display, rear seat entertainment and other infotainment displays, to safety system displays, namely instrument cluster display, head-up display and eMirror systems,” said Stacy Wu, principal analyst for IHS Markit. While today’s volumes are large for infotainment display panels, safety-critical display panels will see double-digit growth through 2022, according to IHS Markit forecasts.

Japan Display, Innolux top tier two automotive display panel manufacturers

Based on the latest findings from IHS Markit, Japan Display, Innolux, Sharp, AU Optronics and LG Display are the top five TFT LCD automotive display panel manufacturers, representing more than 65 percent of the market in 2016.

“However, we expect to see increasing share gains from new entrants and possible ranking switches as well,” Wu said. “Stagnant panel demand from consumer electronics segments like notebooks, tablets, and smartphones, together with excess production capacity, is forcing display panel makers to enter the fast growing automotive market.”

IHS Markit experts covering various aspects of the global displays market will be attending SID’s Display Week in Los Angeles, May 23-25. In addition, IHS Markit will present in these three upcoming display events in the fall:

  • IHS Markit Global Display Conference on September 19-20 in San Francisco, CA
  • IHS Markit Automotive Conference on September 26 in Detroit, MI
  • SID Vehicle Display Symposium on September 26-27 in Detroit, MI