Category Archives: Displays

Researchers have demonstrated nanomaterial-based white-light-emitting diodes (LEDs) that exhibit a record luminous efficiency of 105 lumens per watt. Luminous efficiency is a measure of how well a light source uses power to generate light. With further development, the new LEDs could reach efficiencies over 200 lumens per watt, making them a promising energy-efficient lighting source for homes, offices and televisions.

Researchers created nanomaterial-based white LEDs that exhibit a record high efficiency thanks to quantum dots that are suspended in solution rather than embedded in a solid. The new LEDs could offer an energy-efficient lighting source for homes, offices and televisions. Credit: Sedat Nizamoglu, Koç University

“Efficient LEDs have strong potential for saving energy and protecting the environment,” said research leader Sedat Nizamoglu, Koç University, Turkey. “Replacing conventional lighting sources with LEDs with an efficiency of 200 lumens per watt would decrease the global electricity consumed for lighting by more than half. That reduction is equal to the electricity created by 230 typical 500-megawatt coal plants and would reduce greenhouse gas emissions by 200 million tons.”

The researchers describe how they created the high-efficiency white LEDs in Optica, The Optical Society’s journal for high impact research. The new LEDs use commercially available blue LEDs combined with flexible lenses filled with a solution of nano-sized semiconductor particles called quantum dots. Light from the blue LED causes the quantum dots to emit green and red, which combines with the blue emission to create white light.

“Our new LEDs reached a higher efficiency level than other quantum dot-based white LEDs,” said Nizamoglu. “The synthesis and fabrication methods for making the quantum dots and the new LEDs are easy, inexpensive and applicable for mass production.”

Advantages of quantum dots

To create white light with today’s LEDs, blue and yellow light are combined by adding a yellowish phosphor-based coating to blue LEDs. Because phosphors have a broad emission range, from blue to red, it is difficult to sensitively tune the properties of the generated white light.

Unlike phosphors, quantum dots generate pure colors because they emit only in a narrow portion of the spectrum. This narrow emission makes it possible to create high-quality white light with precise color temperatures and optical properties by combining quantum dots that generate different colors with a blue LED. Quantum dots also bring the advantage of being easy to make and the color of their emission can be easily changed by increasing the size of the semiconductor particle. Moreover, quantum dots can be advantageously used to generate warm white light sources like incandescent light bulbs or cool white sources like typical fluorescent lamps by changing the concentration of incorporated quantum dots.

Although quantum dots embedded in a film are currently used in LED televisions, this lighting approach is not suitable for widespread use in general lighting applications. Transferring the quantum dots in a liquid allowed the researchers to overcome the problematic drop in efficiency that occurs when nanomaterials are embedded into solid polymers.

Making efficient white LEDs requires quantum dots that efficiently convert blue light to red or green. The researchers carried out more than 300 synthesis reactions to identify the best conditions, such as temperature and time of the reaction, for making quantum dots that emit at different colors while exhibiting optimal efficiency.

“Creating white light requires integrating the appropriate amount of quantum dots, and even if that is accomplished, there are an infinite number of blue, green and red combinations that can lead to white,” said Nizamoglu. “We developed a simulation based on a theoretical approach we recently reported and used it to determine the appropriate amounts and best combinations of quantum dot colors for efficient white light generation.”

To make the new LEDs, the researchers filled the space between a polymer lens and LED chip with a solution of quantum dots that were synthesized by mixing cadmium, selenium, zinc and sulfur at high temperatures. The researchers used a type of silicone to make the lens because its elasticity allowed them to inject solutions into the lens without any solution leaking out, and the material’s transparency enabled the necessary light transmission.

The researchers showed that their liquid-based white LEDs could achieve an efficiency double that of LEDs that incorporate quantum dots in solid films. They also demonstrated their white LEDs by using them to illuminate a 7-inch display.

“Quantum dots hold great promise for efficient lighting applications,” said Nizamoglu. “There is still significant room for technology development that would generate more efficient approaches to lighting.”

As a next step, the researchers are working to increase the efficiency of the LEDs and want to reach high efficiency levels using environmentally friendly materials that are cadmium- and lead-free. They also plan to study the liquid LEDs under different conditions to ensure they are stable for long-term application.

BY PETE SINGER

There’s an old proverb that the shoemaker’s children always go barefoot, indicating how some professionals don’t apply their skills for themselves. Until lately, that has seemed the case with the semiconductor manufacturing industry which has been good at collecting massive amounts of data, but no so good at analyzing that data and using it to improve efficiency, boost yield and reduce costs. In short, the industry could be making better use of the technology it has developed.

That’s now changing, thanks to a worldwide focus on Industry 4.0–more commonly known as “smart manufacturing” in the U.S. – which represents a new approach to automation and data exchange in manufacturing technologies. It includes cyber-physical systems, the Internet of things, cloud computing, cognitive computing and the use of artificial intelligence/deep learning.

At SEMICON West this year, these trends will be showcased in a new Smart Manufacturing Pavilion where you’ll be able to see – and experience – data-sharing breakthroughs that are creating smarter manufacturing processes, increasing yields and profits, and spurring innovation across the industry. Each machine along the Pavilion’s multi-step line is displayed, virtually or with actual equipment on the floor – from design and materials through front-end patterning, to packaging and test to final board and system assembly.

In preparation for the show, I had the opportunity to talk to Mike Plisinski, CEO of Rudolph Technologies, the sponsor of the Smart Pavilion about smart manufacturing. He said in the past “the industry got very good at collecting a lot of data. We sensors on all kinds of tools and equipment and we’d track it with the idea of being able to do predictive maintenance or predictive analytics. That I think had minimal success,” he said.

What’s different now? “With the industry consolidating and the supply chains and products getting more complex that’s created the need to go beyond what existed. What was inhibiting that in the past was really the ability to align this huge volume of data,” he said. The next evolution is driven by the need to improve the processes. “As we’ve gone down into sub-20 nanometer, the interactions between the process steps are more complex, there’s more interaction, so understanding that interaction requires aligning digital threads and data streams.” If a process chamber changed temperature by 0.1°C, for example, what impact did it have on lithography process by x, y, z CD control. That’s the level of detail that’s required.

“That has been a significant challenge and that’s one of the areas that we’ve focused on over the last four, five years — to provide that kind of data alignment across the systems,” Plisinski said.

Every company is different, of course, and some have been managing this more effectively than others, but the cobbler’s children are finally getting new shoes.

Smart technologies take center stage tomorrow as SEMICON West, the flagship U.S. event for connecting the electronics manufacturing supply chain, opens for three days of insights into leading technologies and applications that will power future industry expansion. Building on this year’s record-breaking industry growth, SEMICON West – July 10-12, 2018, at the Moscone Center in San Francisco – spotlights how cognitive learning technologies and other disruptors will transform industries and lives.

Themed BEYOND SMART and presented by SEMI, SEMICON West 2018 features top technologists and industry leaders highlighting the significance of artificial intelligence (AI) and the latest technologies and trends in smart transportation, smart manufacturing, smart medtech, smart data, big data, blockchain and the Internet of Things (IoT).

Seven keynotes and more than 250 subject matter experts will offer insights into critical opportunities and issues across the global microelectronics supply chain. The event also features new Smart Pavilions to showcase interactive technologies for immersive, virtual experiences.

Smart transportation and smart manufacturing pavilions: Applying AI to accelerate capabilities

Automotive leads all new applications in semiconductor growth and is a major demand driver for technologies inrelated segments such as MEMS and sensors. The SEMICON West Smart Transportation and Smart Manufacturing pavilions showcase AI breakthroughs that are enabling more intelligent transportation performance and manufacturing processes, increasing yields and profits, and spurring innovation across the industry.

Smart workforce pavilion: Connecting next-generation talent with the microelectronics industry

SEMICON West also tackles the vital industry issue of how to attract new talent with the skills to deliver future innovations. Reliant on a highly skilled workforce, the industry today faces thousands of job openings, fierce competition for workers and the need to strengthen its talent pipeline. Educational and engaging, the Smart Workforce Pavilion connects the microelectronics industry with college students and entry-level professionals.

In the Workforce Pavilion “Meet the Experts” Theater, recruiters from top companies are available for on-the-spot interviews, while career coaches offer mentoring, tips on cover letter and resume writing, job-search guidance, and more. SEMI will also host High Tech U (HTU) in conjunction with the SEMICON West Smart Workforce Pavilion. The highly interactive program supported by Advantest, Edwards, KLA-Tencor and TEL exposes high school students to STEM education pathways and useful insights about careers in the industry.

GLOBALFOUNDRIES today announced that Socionext Inc. will manufacture the third and latest generation of its graphics display controllers, the SC1701, on GF’s 55nm Low Power Extended (55LPx) process technology with embedded non-volatile memory (SuperFlash®). The 55LPx platform enables several new features in Socionext’s SC1701 series including enhanced diagnostic and security protection capabilities, cyclic redundancy code (CRC) checks, picture freeze detection, and multi window signature unit for advanced in-vehicle display systems. The shipping of the SC1701 from Socionext will start at the end of July.

In recent years, the number of in-vehicle electronic systems has risen exponentially with increasing requirements for multiple content-rich displays. Socionext’s SC1701 controller integrates a variety of system component features along with APIX®3 technology and automotive safety functions to meet the increasing demand for high speed video and data connectivity and stringent safety requirements. The device supports display resolution up to one U-HD (4K) or two F-HD (2K) at 30bpp, and capable of receiving two separate video streams over a single link by utilizing the VESA® display stream compression (DSC) method. Moreover, the SC1701 offers video content protection through built-in HDCP decryption technology that enables a richer user experience.

“The SC1701 display controller is designed to support high performance computing within a vehicle, with one of the most innovative evolutions in automotive system architectures,” said Koichi Yamashita, senior vice president and head of IoT and Graphics Solution Business Unit at Socionext. “GF’s automotive grade 1 qualified 55LPx platform, with its low power logic and highly reliable embedded non-volatile memory, was ideal for our product.”

GF’s 55LPx platform, with SST’s SuperFlash® memory technology, provides a fast path-to-product solution, and is fully qualified for consumer, industrial and automotive grade 1 applications. The implementation of SuperFlash® on 55LPx provides a small bitcell size, increased fast read speed along with superior data retention and endurance.

“GF is excited to be working with Socionext, who is a leader in state-of-the-art SoC technology,” said Dave Eggleston, vice president of embedded memory at GF. “Socionext joins our rapidly growing client base for GF’s 55LPx platform, which offers a combination of superior low power logic, embedded non-volatile memory, extensive IP, and superior reliability for the industrial and automotive grade 1 system-on-chip markets.”

The 55LPx-enabled platform is in volume production at GF’s 300mm line in Singapore. In addition to the SC1701, Socionext is currently developing several products on the technology, joining On Semiconductor, Silicon Mobility and Fudan Microelectronics, who are currently optimizing their chip designs with GF’s 55LPx platform for wearable IoT and automotive products.

Process design kits and an extensive offering of silicon proven IP are available now. For more information on GF’s mainstream CMOS solutions, contact your GF sales representative or go to globalfoundries.com.

AMD (NASDAQ:AMD) today announced awards for key suppliers that contributed to the successful launch of 10 new high-performance computing and graphics product families in 2017. The companies honored demonstrated commitment to AMD through excellence in delivery of material, services and technology.

“Our multi-year strategy to design and deliver high-performance products requires a team effort across our global supply chain. Our deep collaboration with our ecosystem of suppliers enables AMD to focus on bringing innovation and choice to the market,” said Keivan Keshvari, senior vice president of Global Operations for AMD. “We look forward to continuing this shared success with our suppliers as market momentum continues to grow for our Ryzen™, Radeon™ and EPYC™ products. Beyond these acknowledgements, AMD extends thanks and appreciation to its entire global network of suppliers for their role supporting our joint success.”

2017 was a successful year for AMD fueled by a record number of innovative product launches delivered to the market. The following suppliers are being recognized as those who played a leading role in enabling these results:

Despite better-than-expected first-quarter demand for thin-film transistor liquid-crystal display (TFT-LCD) TV sets and TV panels, market players would be well advised to adopt a more conservative outlook in demand growth for the coming quarters, according to IHS Markit (Nasdaq: INFO), a world leader in critical information, analytics and solutions.

Earlier market expectations assumed that demand would slow in the first quarter prompted by the observation that TV set makers would put a hold on panel purchases based on hopes that panel prices would drop further. Such a view was largely attributed by the development of Chinese panel makers planning aggressive investments over the next two to three years.

As it turned out, panel makers managed to sell more panels than originally forecasted in the first quarter because panel prices declined much faster than expected. According to IHS Markit, TV panel unit shipments increased by 13.3 percent in the first quarter compared to a year ago, while TV set shipments rose 7.9 percent during the same period.

“LCD TV panel shipments are expected to grow faster than the LCD TV set shipments, expanding the accumulated gap between the two even further,” said Ricky Park, director of display research at IHS Markit.

According to the latest Display long term demand forecast tracker by IHS Markit, the accumulated gap between LCD TV panel and set shipments in the second and third quarters of 2018 is expected to be higher than past 10 years, reaching 8.3 percent and 8.4 percent, respectively, from 7.9 percent in the first quarter. Furthermore, the gap is expected to remain high until 2019.

“The main reason for the higher gap is the aggressive investment in 10.5 generation fabs. TFT LCD capacity, in terms of area, will soar in the next four years,” Park said. “As capacity is expected to increase more than demand, panel suppliers will likely push to sell panels at lower prices while set makers are to hesitate buying panels expecting the price to drop even further.”

However, when the accumulated gap in panel-set shipments is high, an inventory correction should always follow. “TV makers should narrow the gap for healthy inventory control and reducing panel orders is a step in that direction,” Park said. “If TV set makers’ panel purchasing drops, it will likely cause a cash flow issue to panel suppliers, and they would need to reduce the utilization rate to control the supply.”

FlexTech, a SEMI Strategic Association Partner, is now soliciting proposals for projects that advance flexible hybrid electronics (FHE) for sensors, power and other key electronic components. SEMI-FlexTech plans to announce multiple awards to teams or organizations with research and development capability in the U.S. White paper proposals are due July 9, 2018, at 5:00 PM PDT. Review the full Request for Proposal (RFP) for more information about the submission process here.

In partnership with the U.S Army Research Laboratories (ARL), SEMI-FlexTech is seeking proposals for projects that advance heterogeneous packaging for FHE including integrated systems, system architecture and design, and integrated power management components such as batteries, supercapacitors, and energy harvesting.

SEMI-FlexTech’s Technical Council will evaluate and rank proposals, prioritize and manage projects, and administer funding. Grant recipients must match the fund award with cash and in-kind contributions to cover total project cost. Historically, grant recipients have provided, on average, more than 60 percent of project costs. A product demonstration is also required for award consideration.

“This solicitation emphasizes FHE for the Internet of Things (IoT) as we seek to advance the state of the art and incorporate thinned ICs, flexible and printed electronics, power and sensors into a flexible, conformal, low-power package,” explained Melissa Grupen-Shemansky, Executive Director and CTO of SEMI-FlexTech. “The SEMI-FlexTech program is designed to engage multi-disciplinary teams from across the supply chain to develop creative solutions that accelerate the introduction of new FHE technologies.”

SEMI-FlexTech will fund technical approaches that are revolutionary or carry high risk as well as lower-risk evolutionary approaches with shorter development and delivery timetables. SEMI-FlexTech funds research and development initiatives that fall within the U.S. government’s Technology Readiness Levels (TRLs) 3-6 and Manufacturing Readiness Levels (MRLs) 1-3.

The global demand for automotive display systems is expected to continue a strong growth path in 2018, according to recent analysis from business information provider IHS Markit (Nasdaq: INFO).

According to the latest Automotive Display Systems Forecasts , OEM production of the three primary automotive display systems — instrument cluster, center stack and head-up display systems — is expected to reach 118.5 million units globally by the end of 2018, representing a 9 percent growth in volume over 2017. While the volume is growing significantly, the value of the market is growing even faster. In 2018, IHS Markit estimates just these three display systems to bring in $13.5 billion in tier-one supplier revenue, representing a 17 percent growth over 2017.

“In the quest for differentiation, automakers are using displays to transform vehicle interiors into a futuristic digital user experience with more pixels in front of consumers than ever before,” said Brian Rhodes, automotive user experience analyst at IHS Markit. “While high resolution, large displays previously were reserved for luxury applications only, declining average selling prices and increasing consumer demand and production volumes are enabling mass-market car brands to standardize displays that were optional only a few years ago.”

Demand for more displays in automotive applications is strong, but a major enabler to this growth comes from the supply chain. Large global display panel manufacturers in Asia have recently invested heavily in automotive display panel production in order to continue sales growth as display markets in other areas have slowed, such as smartphones and tablet PCs.

According to the latest Automotive Display Market Tracker by IHS Markit, global shipments of automotive display panels are set to increase by 11 percent reaching 164 million units in 2018, following an equally strong 9 percent growth in 2017, which had reached 148 million units.

These two IHS Markit forecasts are fundamentally linked, but also differ in that the shipment forecasts include additional volumes, applications and factors that the current OEM production-side forecasts do not.

“As vehicles adopt more technology, more new display use-cases become viable and new display applications are born,” said Hiroshi Hayase, senior director of small and medium displays at IHS Markit. “In addition to the strong growth in the primary display market, we also expect strong growth in display mirrors, rear seat entertainment and even in aftermarket systems as buyers clamor for more digital interfaces.”

As an example, global display shipments for rearview mirror applications are forecast to soar 52 percent in 2018 to 1.6 million units, beyond the 1.0-million-unit mark set just last year. While automakers are keenly aware of the growing demand in this sector, the aftermarket mirror manufacturers are responding quicker to the trend and represent a majority of today’s global production.

The IHS Markit Automotive Display Systems Forecasts provide customers with demand-side monthly updates to automotive instrument cluster, center stack display and head-up display system forecasts, tracked globally to the segment, OEM, brand, model, platform, and program. Coverage of tier-one suppliers and key technical characteristics like display system size, type, touch, orientation and more enabling a precise view of the volumes, technology and revenue market shares in the industry are also included. Meanwhile, the Automotive Display Market Tracker by IHS Markit contains supply-side quarterly updates of automotive display shipments and revenues by application, size, resolution and technology. It also provides supply chain information between tier-two display suppliers and the rest of the supply chain.

Researchers have demonstrated large-scale fabrication of a new type of transparent conductive electrode film based on nanopatterned silver. Smartphone touch screens and flat panel televisions use transparent electrodes to detect touch and to quickly switch the color of each pixel. Because silver is less brittle and more chemically resistant than materials currently used to make these electrodes, the new films could offer a high-performance and long-lasting option for use with flexible screens and electronics. The silver-based films could also enable flexible solar cells for installation on windows, roofs and even personal devices.

In the journal Optical Materials Express, the researchers report fabrication of a transparent conducting thin-film on glass discs 10 centimeters in diameter. Based on theoretical estimations that matched closely with experimental measurements, they calculate that the thin-film electrodes could perform significantly better than those used for existing flexible displays and touch screens.

“The approach we used for fabrication is highly reproducible and creates a chemically stable configuration with a tunable tradeoff between transparency and conductive properties,” said the paper’s first author, Jes Linnet from the University of Southern Denmark. “This means that if a device needs higher transparency but less conductivity, the film can be made to accommodate by changing the thickness of the film.”

The researchers used an approach called colloidal lithography to create a silver nanopattern that conducts electricity while letting light through the holes. The new transparent electrode films could be useful for solar cells as well as flexible displays and touch screens. Credit: Jes Linnet, University of Southern Denmark

Finding a flexible alternative

Most of today’s transparent electrodes are made of indium tin oxide (ITO), which can exhibit up to 92 percent transparency — comparable to glass. Although highly transparent, ITO thin films must be processed carefully to achieve reproducible performance and are too brittle to use with flexible electronics or displays. Researchers are seeking alternatives to ITO because of these drawbacks.

The anti-corrosive nature of noble metals such as gold, silver and platinum makes them promising ITO alternatives for creating long-lasting, chemically resistant electrodes that could be used with flexible substrates. However, until now, noble metal transparent conductive films have suffered from high surface roughness, which can degrade performance because the interface between the film and other layers isn’t flat. Transparent conductive films can also be made using carbon nanotubes, but these films don’t currently exhibit high enough conductance for all applications and tend to also suffer from surface roughness due to the nanotubes stacking on top of each other.

In the new study, the researchers used an approach called colloidal lithography to create transparent conductive silver thin films. They first created a masking layer, or template, by coating a 10-centimeter wafer with a single layer of evenly sized, close-packed plastic nanoparticles. The researchers placed these coated wafers into a plasma oven to shrink the size of all the particles evenly. When they deposited a thin film of silver onto the masking layer, the silver entered the spaces between the particles. They then dissolved the particles, leaving a precise pattern of honeycomb-like holes that allow light to pass through, producing an electrically conductive and optically transparent film.

Balancing transparency and conductivity

The researchers demonstrated that their large-scale fabrication method can be used to create silver transparent electrodes with as much as 80 percent transmittance while keeping electrical sheet resistance below 10 ohms per square – about a tenth of what has been reported for carbon-nanotube-based films with the equivalent transparency. The lower the electrical resistance, the better the electrodes are at conducting an electrical charge.

“The most novel aspect of our work is that we accounted for both the transmission properties and the conductance properties of this thin film using theoretical analysis that correlated well with measured results,” said Linnet. “Fabrication problems typically make it hard to get the best theoretical performance from a new material. We decided to report what we encountered experimentally and postulate remedies so that this information could be used in the future to avoid or minimize problems that may affect performance.”

The researchers say that their findings show that colloidal lithography can be used to fabricate transparent conductive thin films that are chemically stable and could be useful for a variety of applications.

Global sales of smartphones to end users returned to growth in the first quarter of 2018 with a 1.3 percent increase over the same period in 2017, according to Gartner, Inc. Compared to the first quarter of 2017 sales of total mobile phones stalled and reached 455 million units in the first quarter of 2018.

Nearly 384 million smartphones were sold in the first quarter of 2018, representing 84 percent of total mobile phones sold (see Table 1). “Demand for premium and high-end smartphones continued to suffer due to marginal incremental benefits during upgrade,” said Anshul Gupta, research director at Gartner. “Demand for entry-level smartphones (sub-$100) and low midtier smartphones (sub-$150) improved due to better-quality models.”

Continued weakness in Greater China’s mobile phone market also limited growth potential for the top global brands, including Chinese brands such as OPPO and Vivo, with over 70 percent of their sales coming from Greater China.

Table 1

Worldwide Smartphone Sales to End Users by Vendor in 1Q18 (Thousands of Units)

Vendor

1Q18

Units

1Q18 Market Share (%)

1Q17

Units

1Q17 Market Share (%)

Samsung

78,564.8

20.5

78,776.2

20.8

Apple

54,058.9

14.1

51,992.5

13.7

Huawei

40,426.7

10.5

34,181.2

9.0

Xiaomi

28,498.2

7.4

12,707.3

3.4

OPPO

28,173.1

7.3

30,922.3

8.2

Others

153,782.1

40.1

169,921.1

44.9

Total

383,503.9

100.0

378,500.6

100.0

Source: Gartner (May 2018)

Samsung Growth Slows, Apple Share Increases

Samsung’s midtier smartphones faced continued competition from Chinese brands, which led to unit sales contraction year on year. This is despite the earlier launch of its flagship Galaxy S9/S9+ compared to the S8/S8+ in 2017, and despite the Note 8 having a positive impact on Samsung sales in the first quarter of 2018. Samsung’s smartphone growth rate will remain under pressure through 2018, with Chinese brand’s growing dominance and expansion into Europe and Latin America markets. Samsung is challenged to   raise the average selling price (ASP) of its smartphones, while facing increasing competition from Chinese brands that are taking more market share.

The delayed sales boost for Apple from last quarter materialized. Apple’s smartphone unit sales returned to growth in the first quarter of 2018, with an increase of 4 percent year on year.

“Even though demand for Apple’s iPhone X exceeded that of iPhone 8 and iPhone 8 Plus, the vendor struggled to drive significant smartphone replacements, which led to slower-than-expected growth in the first quarter of 2018,” said Mr. Gupta. “With its exclusive focus on premium smartphones, Apple needs to significantly raise the overall experience of its next-generation iPhones to trigger replacements and lead to solid growth in the near future.”

Huawei and Xiaomi Remained the Big Winners

Huawei’s refreshed smartphone portfolio helped strengthen its No. 3 global smartphone vendor position.

“Achieving 18.3 percent growth in the first quarter of 2018 helped Huawei close the gap with Apple,” said Mr. Gupta. “However, its future growth increasingly depends on the vendor ramping up share in Emerging Asia/Pacific and resolving issues in the U.S. market, through the development of a stronger consumer brand. Huawei’s attempt to grow its premium smartphone portfolio with its recent launches of the P20, P20 Pro and Honor 10 helps raise its competitiveness and growth potential.”

Xiaomi was the clear winner of the first quarter, achieving a growth of 124 percent year on year. Xiaomi’s refreshed portfolio of smartphones and aggressive pricing strategy helped it hold the No. 4 spot in the first quarter of 2018. “This strategy led Xiaomi to achieve 330 percent growth in the Emerging Asia/Pacific region,” said Mr. Gupta.

In the smartphone operating system (OS) market, Google’s Android and Apple’s iOS achieved growth in units in the first quarter of 2018, but Android saw its share slightly contract (see Table 2).

Table 2

Worldwide Smartphone Sales to End Users by Operating System in 1Q18 (Thousands of Units)

Operating System

1Q18

Units

1Q18 Market Share (%)

1Q17

Units

1Q17 Market Share (%)

Android

329,313.9

85.9

325,900.9

86.1

iOS

54,058.9

14.1

51,992.5

13.7

Other OS

131.1

0.0

607.3

0.2

Total

383,503.9

100.0

378,500.6

100.0

Source: Gartner (May 2018)