Real-Time Location System (RTLS) Market Worth $3,923.6 Million by 2020

According to a new market research report “Real-Time Location System (RTLS) Market Product, Technology, Application and Geography – Forecasts & Analysis to 2020“, the global RTLS Market was valued at $720.5 Million in 2014 and is expected to reach $3,923.6 Million by 2020, at an estimated CAGR of 33.03% between 2015 and 2020. The healthcare sector constituted the largest application for the RTLS Market in 2014 and is expected to continue to grow at a significant rate because of increasing applications in the healthcare segment, especially the old age care segment. Industrial manufacturing, government and defense, process industries, and transportation and logistics sectors are the next major applications of RTLS solutions and are expected to grow at a considerable rate due to the increasing adoption of RTLS solutions in the same.

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The RTLS Market players have been focusing on the innovations in terms of technological advancements to cater to the specific needs of enterprises in tracking and monitoring the precise location of assets or personnel. UWB and ZigBee based RTLS technologies have been the emerging technologies in the RTLS Market, which provide high accuracy and precise location of objects in shorter locations compared to any other RTLS technology. The market for these technologies is expected to grow at a higher CAGR in the forecast period than others because of the increasing adoption of the RTLS solutions based on these technologies. Furthermore, these technologies have been able to overcome the difficulties faced by the other technologies in tracking objects in harder mediums such as concrete wall or other substances. However, Wi-Fi and RFID technologies are expected to account for a major market share during the forecast period, due to their lesser cost compared to UWB and ZigBee technologies.

The Americas and Europe were the largest markets for the RTLS technology in 2014. Asia-Pacific is expected to be the fastest growing region, followed by RoW which is also among the major regions that plays a significant role in the growth of the RTLS market. The growth of the RTLS Market in the Americas was largely driven by the U.S., which accounted for 74.7% of the total Americas RTLS Market in 2014. The Asia-Pacific market for RTLS is expected to be driven by its key markets such as Japan, Australia, China,Malaysia, and Singapore. The industrial manufacturing and retail sector along with, transportation and logistics is likely to provide a huge growth opportunity for RTLS solutions in these regions. The market would also be fuelled by the increase in focus of the major global RTLS vendors to expand their product and service offerings in the Asia-Pacific region as this region is expected to witness a higher growth in terms of the adoption of RTLS solutions and market value.

The report describes market dynamics that include the key drivers, restraints, challenges, and opportunities with respect to the RTLS Market and forecasts the market till 2020. This global report provides a detailed view of the RTLS market across products, technologies, applications, and geographies. The report also profiles the prominent players in the RTLS market along with their key growth strategies. The competitive landscape of the market analyses a large number of players with their market share. The RTLS Market is witnessing numerous collaborations and partnerships across the value chain, to cater to various industries in different geographies.

The major companies in the global RTLS Market that have been included in this report are Zebra Technologies Corporation (U.S.), AeroScout, Inc. (U.S.), Savi Technology, Inc. (U.S.), TeleTracking Technologies, Inc. (U.S.), Ubisense Group Plc (U.K.), Ekahau, Inc. (U.S.), Identec Group AG (Liechtenstein), CenTrak, Inc. (U.S.), Awarepoint Corporation (U.S.), and Versus Technology, Inc. (U.S.), and others.

Details of the new RTLS market report, table of contents and ordering information can be found  on Electronics.ca Publications’ web site. View the report:  Real-Time Location System (RTLS) Market Product, Technology, Application and Geography – Forecasts & Analysis to 2020.

 

Real-Time Location System (RTLS) Market Worth $3,923.6 Million by 2020

Mobile Sensing Wearables Market to Reach $47 Billion in 2018

ELECTRONICS.CA PUBLICATIONS announces the availability of a new report entitled “Mobile Sensing Wearables – Market Dynamics Report”.  Annual revenues for mobile sensing wearables – fashionable devices that perform sensing and location functions—will be $47 billion in 2018 driven by widespread adoption of advanced mobile sensing smart watches. Wearable sensors enabled by low power wireless components, mobile apps, cloud computing and a receptive fashion industry has created a technology tsunami for developers and investors.

“Over the past two years, wearables have gone from a niche market to a revolutionary force,” says Mareca Hatler, ON World’s research director. “Developers from all major industries are seeing opportunities for sensor enabled wearables, integrated cloud applications and services as well as the next fashion trend.”

Over the next five years, 700 million wearable tech devices will be shipped for a global annual market worth $47.4 billion at this time. Hardware will make up the majority of the revenues during this period but mobile apps and subscriptions will grow faster. The wearables industry will rapidly create new fashion lines and this is where manufacturers will break new ground.

With over 400 unique products, the mobile sensing wearables market tripled in 2013 over the previous year and continues to accelerate with the emergence of new product categories such as smart watches, smart glasses, consumer wearable sensors as well as growing industrial and enterprise solutions. Out of the 70,000 product reviews that ON World evaluated, 60% were completed in 2013 and the first quarter of 2014. Some categories such as smart watches have increased by a factor of ten and personal sensors increased by over 500 percent.

ON World has identified over 50 smart watch vendors including sports watches, luxury watches and offerings for children such as the HereO GPS watch. By contrast, there are only about a dozen smart glasses developers but they are on track to become a $5 billion market by 2017. A few other emerging mobile sensing wearable product categories include bracelets (e.g., Cuff and Netatmo), baby vital sign monitors (e.g., Rest Devices, Owlet and Enmovere) and pet activity/location trackers (e.g., Tagg, Voyce and Whistle). Investment in wearables hardware companies is accelerating with almost $500 million invested in 2013 alone.

Sensor fusion and cloud based software and services has become the next “killer” platform. Nest’s recently launched developer program is already showing the potential for integrating wearables with smart home systems such as Jawbone’s UP fitness tracker with Nest’s smart thermostats.

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.  View the report:  Mobile Sensing Wearables – Market Dynamics Report.

Mobile Sensing Wearables Market to Reach $47 Billion in 2018

IPC/WHMA-A-620B PDF Download - Requirements and Acceptance for Cable and Wire Harness Assemblies

IPC/WHMA-A-620 is a collection of visual Quality Acceptability Requirements for Cable, Wire and Harness Assemblies.  IPC/WHMA-A-620 can be used as a stand-alone document for purchasing products, however it does not specify frequency of in-process inspection or frequency of end product inspection. No limit is placed on the number of process indicators or the number of allowable repair/rework of defects. Such information should be developed with a statistical process control plan (see IPC-9191).

This publication describes acceptability criteria for producing crimped, mechanically secured, or soldered interconnections and the associated lacing/restraining criteria associated with cable and harness assemblies. It is not the intent of this document to exclude any acceptable procedure used to make the electrical connection; however, the methods used must produce completed assemblies that conform to the acceptability requirements described in this document.

Significant technical updates, greater ease-of-use and compatibility with other key assembly standards are among the many changes users will find in the newly released B revision of IPC/WHMA-A-620, Requirements and Acceptance for Cable and Wire Harness Assemblies. This important industry standard is a joint effort of IPC and the Wire Harness Manufacturers’ Association (WHMA).

The revision addresses more than 500 documented comments and recommendations from users throughout the industry and features 125 new or changed illustrations.

Some of the most extensive changes appear in the molding and potting section, which has been expanded for increased coverage of Class 2 and 3 requirements, including 31 new illustrations. The document also provides new criteria for wires as small as 32 AWG, and has a section on requirements flow down, which requires companies to have their subcontractors use the standard to ensure all hardware is manufactured to the same guidelines.

IPC WHMA A-620B PDF Download

IPC/WHMA-A-620B is 400 pages long and features 682 full-color illustrations.  IPC/WHMA-A-620 B is the latest revision of IPC A620,

Purchase and download IPC/WHMA-A-620B standard from Electronics.ca Publications. IPC standards are also available on CD-ROM.

Also Avaliable in Spanish, Chinese, German, Danish, Polish, and French Versions.

 

IPC/WHMA-A-620B PDF Download - Requirements and Acceptance for Cable and Wire Harness Assemblies

Wi-Fi Semiconductor Chipset Analysis - Wi-Fi Ascending ­ Now More Than Ever

ELECTRONICS.CA PUBLICATIONS announces the availability of a new report entitled “Supplier BullsEye Analysis 802.11ac WiFi Chipsets”.  According to the oft-cited Cisco Visual Networking Index, by 2018, Wi-Fi becomes the most important air interface (and possibly the most important broadband wireless communications interface bar none).

Exhibit 1: Global IP Traffic by Local Access Technology

2×2 MIMO 802.11ac is now a standard feature in new smartphones, phablets, tablets and notebook computers. We believe that in 1H15 2015, new iOS and Android radio firmware will turn on Multi User MIMO (MU-MIMO) functionality in smartphones, potentially quadrupling Wi-Fi throughput as 11ac Wave 2 Access Points are deployed.

At the International CES 2015 event in early January 2015, all eight of the semiconductor suppliers analyzed in this report made announcements regarding their IEEE 802.1ac product portfolios. The battle for new design wins and subsequent market share had shifted and become significantly more complex.

Qualcomm and Broadcom are in a horse race now for Wave 2 consumer gateway and enterprise access point design wins. Broadcom has strong Wave 1 design win momentum, while Qualcomm has a product maturity advantage.

Marvell has a strong new Wave 2 chipset offering, a deep Ethernet packet processing experience, but few existing 11ac design wins. We believe Marvell is the dark horse in the 2015 race for Wave 2 chipset market share.

Quantenna has the most market experience with Wave 2 802.11ac radios. As evidence of their technical prowess, they demonstrated an 8×8:8 “Wave 3″ (EJL Wireless Research designation) solution at CES 2015. We believe the company is an attractive acquisition for a strong embedded processing semiconductor company.

For a small venture-backed company, Celeno has an impressive set of design wins. An acquisition by their set top box design partner Intel would enable Intel to increase their “share of wallet” in consumer cable modem WLAN gateway systems.

MediaTek has stepped up with a Wave 2 radio and powerful Wi-Fi networking SoC, and while late to the game, they offer a complete smartphone chipset portfolio, providing client side leverage for their Wi-Fi access point chipset solution.

Intel has taken an early market lead with IEEE 802.11ad WiGig. The question remains whether they will see consumer interest and PC OEM uptake of this new short range 60 GHz air interface in 2015.

Realtek faces a serious threat from Broadcom’s new single chip 2×2 11ac product family. 2015 will be a critical year for Realtek’s future in Wi-Fi silicon.

This research report is intended as a companion to another Wi-Fi Semiconductor Chipset Analysis “Wi-Fi Blasts Ahead with 11ac Wave 2 Chipsets“, published in December 2014.

This research report analyzes eight 802.11ac Wi-Fi equipment chipset suppliers (three radio only and five radio plus Wi-Fi networking processor SoC) using objective commercial and technical performance fitness evaluation criteria. Alphabetically, these suppliers are:

• Broadcom Corp


• Celeno Communications (radio only)


• Intel Corp (radio only)


• Marvell Technology Group


• MediaTek, Inc.


• Qualcomm Technology, Inc.


• Quantenna Communications, Inc. (radio only)


• Realtek Semiconductor Corp

This research report does not cover products from Airoha, Intersil or Lantiq, as none of these companies offers 802.11ac radios or companion networking processors SoCs. Redpine Signals was removed from this report, as the company has no known 802.11ac equipment design wins. EVALUATION CRITERIA RATIONALIZATION Criterion 1 ­ Complete 802.11ac Wave 1 or Wave 2 Chipset (Radio plus Wi-Fi Networking Processor SoC).

With a very small number of exceptions, enterprise and carrier Wi-Fi access point OEMs (and their ODM partners typically in Taiwan) are unwilling to mix radios and networking processor SoC in their system designs. There are numerous compelling reasons for this industry dynamic. First, complete “homogeneous” (single supplier) chipset suppliers optimize system performance for their own radio and networking SoC (plus one or two third-party RF front end designs), and these suppliers are generally unwilling to optimize system performance for system designs that include competitor silicon and software (this optimization process generally requires release of proprietary firmware or software source code, for example). This means the equipment OEM must optimize a “mixed supplier” chipset themselves. To make matters worse, the chip suppliers will typically hold back on application engineering support to customers attempting to integrate and optimize a “heterogeneous” (multiple supplier) chipset, both because of ambiguous technical accountability, and to apply business leverage on the equipment OEM to abandon the heterogeneous design, and adopt the supplier’s complete homogeneous chipset. Additionally, the semiconductor suppliers will typically provide more attractive pricing for a complete chipset design win than for discrete radio or networking SoC chips.

The R&D and sustaining engineering support resources required by the equipment OEM to integrate and optimize a heterogeneous chipset are much higher than using a complete reference design from a single supplier. Clearly there would have to be a major technical benefit (much higher performance, much lower power, much smaller form factor) to a heterogeneous chipset to justify the higher marginal manufacturing cost and the much higher development and support costs. There is little or no compelling evidence of any “breakthrough level” technical benefit in the publically available test results published by access point equipment OEMs using heterogeneous chipsets.

The particular criterion is “binary”: complete radio plus Wi-Fi networking processor SoC suppliers receive four points; and radio only suppliers receive one point. There are no intermediate point scores between one and four. One point is awarded to radio only suppliers because in all cases they have reference design relationships with Wi-Fi networking processor SoC suppliers such as Lantiq, Freescale and Intel.

Due to this industry dynamic, suppliers who can offer complete 802.11ac chipsets (radio plus networking SoC) have an overwhelming commercial advantage over those suppliers who offer discrete radios or discrete networking processor SoCs, and thus this criterion is ranked #1 in the EJL Wireless Research Wi-Fi Chipset Supplier BullsEye Analysis.

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site. View the report: Supplier BullsEye Analysis 802.11ac WiFi Chipsets.

 

Wi-Fi Semiconductor Chipset Analysis - Wi-Fi Ascending ­ Now More Than Ever

Radio Chip for the “Internet of things”

Circuit that reduces power leakage when transmitters are idle could greatly extend battery life

At this year’s Consumer Electronics Show in Las Vegas, the big theme was the “Internet of things” — the idea that everything in the human environment, from kitchen appliances to industrial equipment, could be equipped with sensors and processors that can exchange data, helping with maintenance and the coordination of tasks.

Realizing that vision, however, requires transmitters that are powerful enough to broadcast to devices dozens of yards away but energy-efficient enough to last for months — or even to harvest energy from heat or mechanical vibrations.

“A key challenge is designing these circuits with extremely low standby power, because most of these devices are just sitting idling, waiting for some event to trigger a communication,” explains Anantha Chandrakasan, the Joseph F. and Nancy P. Keithley Professor in Electrical Engineering at MIT. “When it’s on, you want to be as efficient as possible, and when it’s off, you want to really cut off the off-state power, the leakage power.”

This week, at the Institute of Electrical and Electronics Engineers’ International Solid-State Circuits Conference, Chandrakasan’s group will present a new transmitter design that reduces off-state leakage 100-fold. At the same time, it provides adequate power for Bluetooth transmission, or for the even longer-range 802.15.4 wireless-communication protocol.

“The trick is that we borrow techniques that we use to reduce the leakage power in digital circuits,” Chandrakasan explains. The basic element of a digital circuit is a transistor, in which two electrical leads are connected by a semiconducting material, such as silicon. In their native states, semiconductors are not particularly good conductors. But in a transistor, the semiconductor has a second wire sitting on top of it, which runs perpendicularly to the electrical leads. Sending a positive charge through this wire — known as the gate — draws electrons toward it. The concentration of electrons creates a bridge that current can cross between the leads.

But while semiconductors are not naturally very good conductors, neither are they perfect insulators. Even when no charge is applied to the gate, some current still leaks across the transistor. It’s not much, but over time, it can make a big difference in the battery life of a device that spends most of its time sitting idle.

Going negative

Chandrakasan — along with Arun Paidimarri, an MIT graduate student in electrical engineering and computer science and first author on the paper, and Nathan Ickes, a research scientist in Chandrakasan’s lab — reduces the leakage by applying a negative charge to the gate when the transmitter is idle. That drives electrons away from the electrical leads, making the semiconductor a much better insulator.

Of course, that strategy works only if generating the negative charge consumes less energy than the circuit would otherwise lose to leakage. In tests conducted on a prototype chip fabricated through the Taiwan Semiconductor Manufacturing Company’s research program, the MIT researchers found that their circuit spent only 20 picowatts of power to save 10,000 picowatts in leakage.

To generate the negative charge efficiently, the MIT researchers use a circuit known as a charge pump, which is a small network of capacitors — electronic components that can store charge — and switches. When the charge pump is exposed to the voltage that drives the chip, charge builds up in one of the capacitors. Throwing one of the switches connects the positive end of the capacitor to the ground, causing a current to flow out the other end. This process is repeated over and over. The only real power drain comes from throwing the switch, which happens about 15 times a second.

Turned on

To make the transmitter more efficient when it’s active, the researchers adopted techniques that have long been a feature of work in Chandrakasan’s group. Ordinarily, the frequency at which a transmitter can broadcast is a function of its voltage. But the MIT researchers decomposed the problem of generating an electromagnetic signal into discrete steps, only some of which require higher voltages. For those steps, the circuit uses capacitors and inductors to increase voltage locally. That keeps the overall voltage of the circuit down, while still enabling high-frequency transmissions.

What those efficiencies mean for battery life depends on how frequently the transmitter is operational. But if it can get away with broadcasting only every hour or so, the researchers’ circuit can reduce power consumption 100-fold.

This research was funded by Shell and Texas Instruments.

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Written by Larry Hardesty, MIT News Office

Related links

Wireless Charging Technology: Receiver and Transmitter ICs Worldwide Forecasts

Radio Chip for the “Internet of things”

Digital Power Management ICs Market Report

ELECTRONICS.CA PUBLICATIONS announces the release of a comprehensive global report on Digital Power Management ICs markets.  Global market for Digital Power Management ICs is forecast to reach US$4.5 billion by 2020, driven by rising use of digital power solutions across various power system designs. Digital power management ICs (DPMIC) are capable of performing several functions including power management, power conversion, and communication by using a digital feedback loop.

Power management is carried out within and on-board the converter. Select on-board functions performed by digital power management ICs include power system configuration, voltage sequencing, and fault monitoring. Functions within power converter include digital implementation of PWM (pulse width modulator) for controlling energy flow for each cycle. DPMIC’s significant advantages over their analog counterparts in terms of level of performance and efficiency in adapting, controlling and rectifying power current are helping drive the market’s strong evolution.

Demand for digital power management IC’s is intrinsically linked to the level of semiconductor device manufacturing activity, which in turn is largely influenced by the health of the electronic devices manufacturing sector. The market as a result remains vulnerable to fast-changing technology, short product life cycles, and rapid obsolescence of semiconductor devices. Periods of economic slowdown such as the 2007-2009 economic recession slowed down demand for electronic devices, which in turn impacted market prospects for semiconductor devices and digital power management IC’s. The market however made a strong rebound in the year 2010 and current growth is driven by increasing demand for and production of electronic devices.

The market is also expected to be driven by robust growth in numerous application areas such as computer networks, telecommunications and data communications all of which require management of multiple voltage rails and high power. Technology developments aimed at enhancing cost-effectiveness and product performance will benefit market prospects in the coming years. Auto tuning and auto compensation are significant developments in digital control technology. Load shedding, dimming and developing lighting automation are all likely to propel the implementation of digital control methods in ballast technology. New digital product architectures and designs are likely to be developed that emphasize on more accurate current and voltage regulation. Growing acceptance in the mainstream desktop, graphic and server markets is also expected to push adoption.

As stated by the new market research report on Digital Power Management ICs, Asia-Pacific represents the largest market worldwide. The region also represents the fastest growing market with a CAGR of 34.1% over the analysis period. Large population base, rising levels of disposable income, rapidly growing semiconductor manufacturing industry and favorable government initiatives have established Asia as the world’s largest supplier as well as consumer of electronic products. China is a major contributor to the consumption as well as supply of power management ICs supported by low production costs, rising levels of literacy, and presence of efficient infrastructure facilities.

Key players covered in the report include Analog Devices Inc., Ericsson Power Modules AB, Exar Corporation, Fairchild Semiconductor Inc., Freescale Semiconductor Inc., Infineon Technologies AG, International Rectifier Corporation, Intersil Corporation, Linear Technology Corporation, Maxim Integrated Products Inc., Micrel Inc., Microchip Technology Inc., Power-One Inc., Silicon Laboratories Inc., Skyworks Solutions Inc., Qualcomm Incorporated, and Texas Instruments Incorporated, among others.

The research report titled “Digital Power Management ICs – Global Strategic Business Report”, provides a comprehensive review of market trends, growth drivers, technological trends, major challenges, mergers, acquisitions and other strategic industry activities of major companies worldwide. The report provides market estimates and projections for major geographic markets including the US, Canada, Japan, Europe (France, Germany, Italy, the UK, Spain, Russia, and Rest of Europe), Asia-Pacific (China, South Korea, Taiwan, and Rest of Asia-Pacific) and Rest of World. Key end-use markets analyzed in the report include Electronics; Data Communications, Computer Networks & Telecommunications; and Other Application Types.

Digital Power Management ICs Market Report

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.  View the report: Digital Power Management ICs – Global Strategic Business Report.

 

Digital Power Management ICs Market Report

IPC Working Group Focuses on Nuances of Conformal Coating

As products get smaller and denser, factors that used to be fairly easy to deal with can become areas of concern. Conformal coatings are getting increased interest now as usage grows and the quality of coatings comes under more scrutiny.

These coatings have typically been applied and examined using a range of related standards. For example, IPC-CC-830 addresses some basic testing of materials properties, while IPC J-STD-001 and IPC-A-610 define how a cured film should look.

A new IPC working group, 5-33awg, Conformal Coating Requirements Working Group, was formed to leverage the considerable amount of coating experience of the 5-33c IPC Conformal Coating Handbook Task Group, and focus on areas not covered by existing specifications. Among their areas of interest are the differences in the ways that an aerospace OEM might test coatings for NASA for outer space, or for the FAA’s tests on humidity condensation. Testing automotive OEM coatings in a damp heat environment is another area being examined.

5-33awg is working to develop criteria for conformal coating application and evaluation. Its goal is to come up with methods that allow a user of conformal coating to determine how conformal coating performs in particular end-use environments.

Learn more about conformal coatings market and  IPC Standards that provide informed perspective and relevant analysis of emergent technologies.

 

 

IPC Working Group Focuses on Nuances of Conformal Coating

32KHz and Real Time Clocks

ELECTRONICS.CA PUBLICATIONS announces the availability of a new market research report entitled “32 KHz and Real Time Clocks” focused in semiconductor timing: 32 KHz and Real Time Clocks (RTC’s). This second in a series of CS &A LLC research studies provides a deep dive into both 32 KHz references and Real Time Clocks (RTC’s).  Last year we offered the first in the series; Semiconductor Timing Opportunities in Communications Infrastructure and Back Haul, with this second release geared specifically toward Time of Day generation and tracking.

Long a semiconductor category in Power Management under the heading of Supervisory, CS &A has, since 2005, considered both the 32 KHz Reference, Oscillators, and Real Time Clock IC’s as a Semi Timing product category and put it in with other IC Timing solutions under our Semiconductor Clock and Timing Reporting and considered a factor in the ~$7 B USD Semi Timing Market.

This report provides a deep and comprehensive look into both the 32 KHz reference and the Real Time market with all of its sub categories; Simple Commodity, Complex Commodity, Precision, and Fully Integrated solution categories that have emerged to provide a wide swath of solutions from the cheap (pennies and dimes), to as much as $18 USD for fully integrated solutions complete with the resonator, oscillator, dividers, full featured registered sets, on board NVM and scratchpad memory, and the battery and charging circuits…

Mark Sherwood, Principal Associate and CEO at CS &A LLC says: ” This is a deep dive into the 32 KHz reference and Real Time Clock Solutions that combined in CY2013 generated in excess of $500 Million USD WW.

The report details: WW TAMs, Supplier listings, product category reporting by volume, device level $ASP, and $revenue roll ups, plus technology reporting and analysis for Quartz, MEMS and Compensated CMOS based solutions. It is the only standalone report and analysis for this segment of Semiconductor Timing available and provides insights from the inside of this key industry segment, and actionable material and information to help guide the reader thru a complicated technology base, a mix of high and low level suppliers, a crowded channel, and key OEM’s consuming high volume for specific applications.”

32 KHz standalone references include: standalone resonators-, quartz crystal, MEMS resonators, or implemented as an Oscillator module with closed loop calibration and a compensation loop providing a multitude of solutions in the market today at a variety of levels of performance. Today, the 32 KHz Solution Mix includes XO, TCXO, DCTCXO, and standalone resonators/crystals/CMOS, with standalone Quartz solutions dominant in volume and share, DCTCXO, and simple XO type oscillators have a good SOM, and continue to grow in volume/SOM while experiencing hard $ASP erosion. One new opportunity for these kind of solutions has emerged from the growing Wearable’s Market, and as you can imagine in this application that low power consumption, low voltage tolerant (battery based applications) small form factor, and low price are mission critical items in order to play.

32KHz and Real Time Clocks

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site. View the report: 32 KHz and Real Time Clocks.

32KHz and Real Time Clocks

Magnetic Field Sensors Market Analysis

ELECTRONICS.CA PUBLICATIONS announces the availability of a new report entitled “Magnetic Field Sensors Market by Type, Technology, Applications and Geography – Forecasts & Analysis to 2013 – 2020″. The market size of the magnetic field sensors market is expected to grow from the $1.6 Billion that it accounted for in 2013 to $2.9 Billion by 2020, at an estimated CAGR of 8.04% from 2014 to 2020. The volume of the magnetic sensors is currently estimated to be 5.9 billion units and is expected to rise up to 9.6 billion units at an estimated CAGR of 6.75% from 2014 to 2020.

A magnetic field sensor identifies the position of an object on the basis of a magnetic field. This is built up either by an external permanent magnet or by a magnet integrated in the sensor. For example, movements of gear wheels or approximation of objects result in alterations inthe magnetic field. These changes are detected by the sensor and evaluated by the integrated electronics. Depending on the sensor type, the output signal may be digital or analog.Magnetic sensors are non-contact electronic sensors. They detect magnetic fields or their alteration by ferromagnetic objects.

There are many approaches towards magnetic sensing, which include Hall effect sensors, AMR magnetic sensors, GMR magnetic sensors, tunnel magnetoresistance sensors, nuclear precession magnetic field sensors, optically pumped magnetic field sensors, fluxgate magnetometer, search coil magnetic field sensors, and SQUID magnetic field sensors. MEMS-based magnetic field sensors can offer small-size solution for magnetic field sensing. Smaller device can be placed closer to the measurement spots, thereby achieving higher spatial resolution. Additionally, MEMS magnetic field sensor does not involve the micro fabrication of magnetic material. Therefore, the cost of the sensor can be largely reduced. Integration of MEMS magnetic field sensor can further reduce the size of the entire magnetic field sensing system.

New developments in the automobile infotainment systems will also increase the demand of the magnetic field sensors.The largestapplications of the magnetic field sensors in the automobile sectorare found in theAnti-Lock BrakingSystems (ABS) and engine control management systems, which are gaining popularity in the emerging markets.

This report covers the vital driving and restraining factors for this market. Encouraging government legislations and policies foreco friendly vehicles, increase in the need of efficient products, and rise in the applications of magnetic sensors in the automobiles and consumer electronics are acting as the driving factors for this industry. However, there are few factors, which are acting as obstacles in the growth of the magnetic sensor market. These factors are inconsistency of a magnetic body, distortional variation, temperature fluctuations, and low resistance in magnetic field detection. Unavailability of aftermarket is a strong restraint for the magnetic field sensor market.

The worldwide market of the magnetic field sensors is segmented into North America, Europe, APAC, and RoW. APAC is the leading geography in this market due to the supporting factors present in the APAC region; such assupportive government policies, increasing demand for automobiles and smart phones in this region,and presence of key industry players. However, North America which is another vital market is expected to show a significant growth in the coming years due to revised government policies and expansion of the magnetic sensorsbusiness in this region, by players such as Honeywell International (U.S.) and Allegro MicroSystems Inc. (U.S.).

This report profiles the major companies which have beencontributing significantlyin this market; these include Allegro MicroSystems Inc. (U.S.), Infineon (Germany), Asahi Kasei Microdevices Corporation (Japan), Austria microsystems AG (Germany), Honeywell International (U.S.), Robert Bosch GmbH (Germany), MEMSIC Inc. (U.S.), Melexis Microelectronic Systems (Belgium), Micronas Semiconductor (Switzerland), and NXP Semiconductors (The Netherlands).

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.  View the report: Magnetic Field Sensors Market by Type, Technology, Applications and Geography – Forecasts & Analysis to 2013 – 2020.

Magnetic Field Sensors Market Analysis

Structural Electronics - A Business of Tens of Billions of Dollars Within the Coming Decade

Structural electronics  is one of the most important developments this century yet most people have never heard of it. Strange – there are over 37 million items on Google. Two years ago, IEEE published,”3D Printing for Rapid Prototyping of Structural Electronics”. Drayson revealed the “structural battery” in the aerofoil of its pure electric racing car. Tesla amazed us with an empty engine compartment and trunk in its pure electric car – the power train was entirely fitted into the sides and floor.

Fitting things into spare spaces, though it attracts the name, is really only a precursor of structural electronics. As covered in the reports, Future Technology for Hybrid and Pure Electric Cars and Structural Electronics, a much bigger gain comes when existing dumb metal and plastic are not needed because load-bearing electronics and electrics take over. A faster payback and much greater saving in weight and space result. Indeed, many other benefits accrue. Laminar batteries in the wings of an aircraft may not need water cooling because of their shape.

Load-bearing supercapacitors have already been made into a car trunk lid by Imperial College London and Vanderbilt University in the USA and others are doing similar things. Universities rarely use the term structural electronics for what they are doing – they prefer a longer string of words. Building Integrated Photovoltaics BIPV is not yet seen by proponents as a subset of structural electronics even though integral energy storage and circuitry is being explored. From aircraft fuselages having a human-like nervous system to the front panel of your washing machine being the electronics, the terminology is more likely to be manufacturing-oriented such as, “in-mold electronics”.

Nonetheless the big picture is structural electronics taking over from a century of joining components together and putting them in a box. Now is the century of electronic and electrical structures with a very different value chain. Providers of chemicals, laminates, composites, 3D electronic printing, smart skin for structures and, yes, in-mold electronics step forward.

The following pages are taken from the report “Structural Electronics 2015-2025: Applications, Technologies, Forecasts“.  This research appraises the market opportunity, assesses technologies, the competitive landscape, value chain drivers, barriers, case studies and global trends.

Structural electronics market forecast by component type for 2014-2024 in US $ billions, for printed and potentially printed electronics including organic, inorganic and composites

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.  View the report: “Structural Electronics 2015-2025: Applications, Technologies, Forecasts“.

 

Structural Electronics - A Business of Tens of Billions of Dollars Within the Coming Decade

Military Communications Market: A $40 Billion Opportunity

ELECTRONICS.CA PUBLICATIONS announces the availability of a new report entitled “The Military Communications Market: 2015 – 2030 – Opportunities, Challenges, Strategies & Forecasts”. According to this study, the military communications market will account for over $40 Billion in revenue by 2020. Armed forces throughout the globe rely on communication systems to enable information sharing and securely stay in constant contact. The role of these systems continues to grow in importance, with new mission areas such as the control of unmanned vehicles and time-critical targeting heavily reliant on network connectivity.

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Despite pressures on overall defense expenditure, a universal trend towards network centric warfare combined with an unstable geopolitical landscape, is continuing to drive significant investments in military communications. The market is expected to account for over $40 Billion in revenue by the end of 2020, with investments ranging from the adoption of multi-band and multi-mode tactical radio systems, to the integration of ad hoc networking platforms in unmanned vehicles.

The “Military Communications Market: 2015 – 2030 – Opportunities, Challenges, Strategies & Forecasts” report presents an in-depth assessment of the military communications ecosystem including key trends, market drivers, challenges, enabling technologies, regional investment landscape, submarkets, leading applications, opportunities, future roadmap, value chain, ecosystem player profiles and strategies. The report also presents market size forecasts for military communications from 2015 through to 2030. The forecasts are segmented for 6 submarkets, 3 service branch classifications, 5 regions and 50 leading countries.Military organizations worldwide are increasingly moving away from proprietary, one-off, unique communication systems that are expensive in favor of similar, and often more advanced, systems readily available in the commercial marketplace at reduced costs from a variety of vendors.

Military Communications Market

The report will be of value to current and future potential investors into the military communications market, as well as armed forces, system integrators and vendors who wish to broaden their knowledge of the ecosystem.  Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.  View the report: “The Military Communications Market: 2015 – 2030 – Opportunities, Challenges, Strategies & Forecasts“.

Military Communications Market: A $40 Billion Opportunity

Security Devices for Connected Homes Market: -- Markets Reach $7.7 Billion By 2021

ELECTRONICS.CA PUBLICATIONS announces the availability of a new study “Security Devices For Connected Homes: Market Shares, Strategy, and Forecasts, Worldwide, 2015 to 2021″.  Next generation home security devices achieve a complete replacement of existing security systems, 3D video cameras, automated connected thermostats, access sensors, and intrusion detection devices can al alert a person on the smart phone. Devices are wireless, are more energy efficient, last longer and have a significantly lower cost of operation. The study has 366 pages and 116 table and figures.

With successful strategies for increased market presence, product leadership and cost-efficiency, apps are well positioned for continued long-term profitable growth driven by the major economic trends: urbanization, rapid technological development and increased security requirements.

There is significant innovation in the market for the connected home. Lower hardware prices, increased bandwidth availability, abundance of cloud capacity, sensor miniaturization, advances in wireless standards and mobile device smart phone evolution are market forces. Improved interfaces and alerting systems are the foundation for the connected home.

Home integrated networks implement home energy management (HEM) and security for the connected home. The connected home is evolving into a multibillion-dollar industry as people use the apps on their smart phone to substitute for a security monitoring service. The smart phone can send alerts and allow control of lighting. As wireless communication standards evolve to support systems integration, home owners gain more control of the living environment through remote access controlled by apps on the smart phone.

Growth has huge implications for energy efficiency and demand response. The plethora of wireless communication standards include Wi-Fi, ZigBee, Z-Wave, Thread, and Bluetooth LE. Numerable platforms are available. A lack of standards has presented a substantial barrier to overall smart home adoption by limiting interconnectivity between devices. The best security products to keep the home and family safe are interconnected modules.

2014 saw a wide expansion of security based do-it-yourself (DIY) home devices. Hub-based systems, point solutions, modules, and kits were available as self-install home security units. Security systems are part of a larger smart home systems market. Early adopters are adding to units already in place. The new modules are interconnected to apps on the smart phone.

Point solutions category are primarily focused on security. The broader set of connected home solutions have modules that range from thermostats, doorbells and ceiling fans to slow cookers and irrigation controllers. Crowdfunding sites like Indiegogo played a major role in helping drive funding for connected home devices and startups.

Consumers, especially in younger generations, expect mobile apps, security cameras, and mobile notification features with their home security systems. Older generations and the non-do-it-yourselfers have a hard time with installation and maintenance of DIY connected home solutions. The combination of needs from both the young and old are creating a favorable environment for strong sustained growth in the Do-It-For-Me (DIFM) interactive security and connected home space.

According to Susan Eustis, leader of the team that prepared the study, “In 2014 the Security for Connected Homes saw a large number of big-name acquisitions and entries. Samsung made an acquisition of SmartThings. Google’s acquisitions were of Nest, Dropcam and Revolv. Apple acquired HomeKit. Quantities of fielded point devices and systems increased. What defines the market is the ability of a device to connect to a smart phone app and send alerts directly from a connected device to a remote smart phone”

Open platforms and device interoperability help consumers preserve their investments by building on top of their existing connected home devices and services. This compatibility also expands the value of connected homes by linking previously isolated devices and services, further enhancing peace of mind and convenience in the home. The hope is to offer consumers a more unified experience by giving them access to all of their devices from a single app or interface and enabling interactions and automation between previously isolated devices and services.

Security Devices for Connected Homes Market

Security devices for the connected home markets at $1.2 billion in 2014 are forecast to reach $7.7 billion dollars, worldwide by 2021. The continuation of 2014 trends, combined with low market awareness of the value of home automation, will force many connected home vendors to pivot and offer more than simple apps for device monitoring and control. This leads us to a big trend for 2015: movement toward interoperability between vendors, devices and platforms.

Security Devices For Connected Homes: Market Shares, Strategy, and Forecasts, Worldwide, 2015 to 2021

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.
View the report: “Security Devices For Connected Homes: Market Shares, Strategy, and Forecasts, Worldwide, 2015 to 2021“.

Security Devices for Connected Homes Market: -- Markets Reach $7.7 Billion By 2021

Microcontrollers, DSP & IP-Core Chip Market

According to a new market research report “Microcontrollers, DSP, & IP-Core Chip Market by Type, Application (Automotive & Transportation, Consumer Electronics, Industrial, Communications, Security, Medical & Healthcare) and Geography (North America, South America, Europe, APAC, & ROW) – Analysis & Forecast to 2014 – 2020″, the Microcontrollers, DSP, & IP-Core Chip Market is expected to reach $41.69 Billion by 2020, growing at a CAGR of 6.96% from 2014 to 2020.

Technological advancement in the automobile sector has given rise to the Microcontrollers, DSP, & IP-Core Chip Market. Consumers are demanding various solutions in automotive applications such as Advanced Driver Assistance Systems (ADAS), engine control unit, automotive infotainment, in-vehicle networking, and more, which has further lead the demand for microcontrollers. Smartphone market also witnesses the growth of the microcontroller market. Microcontroller is one of the important components in smartphone and is poised to witness major growth as the embedded processing is becoming more complex, which is further driving the market.

Increasing the number of wireless devices and requirement of wireless infrastructure are increasing the demand of Digital Signal Processors (DSP). Wireless communication requires high signal performance at reduced power consumption, which has eventually enhanced the multi-core DSP market. IP video surveillance also drives the demand of DSPs that provide features such as remote monitoring, lower cost installation, and centralized backup and storage.

The report’s detailed segmentations by product type, core type, IP nature, customization, applications, and geography cover all the existing and emerging technologies in the Microcontrollers, DSPs, & IP core chips market. Microcontroller market segmented by type, 8-bit, 16-bit, and 32-bit. DSP market segmented by product segments and core types, Product segment of DSP consists of general purpose DSP, application specific DSP, and programmable (FPGA & PLD) DSP; the core type segment consists of single-core DSP processor and multi-core DSP processor. IP-core chips market segmented by IP nature and customization, IP nature consists of soft core and hard cores. Customization segment consists of standard IP core and customizable IP core.

The application segmentation of the market covers all the major applications such as automotive and transportation, consumer electronics, industrial building and home, security, communications, and medical and healthcare market in detail.

One of the objectives of the research study was to analyze the market trends for each of the microcontrollers, DSPs, and IP core chips products segments; and the growth rates of the various product segments.

Apart from market segmentation, the report also includes in depth analysis such as Porter’s five force analysis, value chain with detailed process flow diagram, and market dynamics such as drivers, restraints, and opportunities for the microcontroller, DSPs, & IP core chips market.

Microcontrollers, DSP & IP-Core Chip Market Report

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.  View the report: Microcontrollers, DSP, & IP-Core Chip Market by Type, Application (Automotive & Transportation, Consumer Electronics, Industrial, Communications, Security, Medical & Healthcare) and Geography (North America, South America, Europe, APAC, & ROW) – Analysis & Forecast to 2014 – 2020

Browse Related Reports:

Semiconductor (Silicon) IP Market by Form Factor (Integrated Circuit IP, SOC IP), Design Architecture (Hard IP, Soft IP), Processor Type (Microprocessor, DSP), Application, Geography and Verification IP – Forecast & Analysis to 2013 – 2020

Digital Signal Processors Market, Global Forecast & Analysis (2011-2016) – Focus On Customizable, Embedded, Programmable (FPGA & PLD), Application Specific (ASIC) Based DSP Chips, DSP System-On-Chips And Intellectual Property (IP) Markets

 

Microcontrollers, DSP & IP-Core Chip Market

Graphene in Electronics and Energy

The current overall graphene market is estimated to be between US$13-$15 million. However this will grow significantly in the next 10 years and is likely to be larger than projected figures from a number of market consultancies. For example, XG Sciences have over 600 customers in the automotive, electronics, battery and aerospace industries, and the company generated $4 million in revenue in 2012. Most of the major graphene producers have relationships with electronics and battery OEMs.  Details of the new report, table of contents and ordering information can be found

on Electronics.ca Publications’ web site. View the report: Graphene in Electronics and Energy.

Driven by demand from markets where advanced materials are required, graphene promises to outstrip all current nanomaterials, especially in electronics and energy storage applications. Other markets graphene is impacting include aerospace, automotive, coatings and paints, communications, sensors, solar, oil, and lubricants. The exceptional electron and thermal transport, mechanical properties, chemical stability of graphene and combinations thereof make it a potentially disruptive technology for electronics and energy applications.

Applications are coming onto the market for polymer composites and EMI shielding coatings. Graphene-based conducting inks are also finding their way into smart cards and radio-frequency identification tags. China is expecting to bring graphene products to the market in 2014 in consumer electronics. Companies such as IBM and Samsung are pursuing applications for graphene in electronics and optics. Most major Li-ion battery manufacturers and electronics companies, especially in Asia, have significant research initiatives in graphene.

Many of the current and potential applications of carbon nanotubes may be taken by graphene, as it displays enhanced properties but with greater ease of production and handling. In this regard, carbon nanotubes may be viewed as a stalking horse for commercial applications of graphene. In the next 2-3 years there is likely to be graphene enabled-applications in ultra thin flexible Li ion batteries, large supercapacitors, water membranes, biosensors, optical sensors, solar cells and conductive composites.

The projected “killer app” for graphene has been identified as transparent conductive films for displays, but that is not proven yet. Enhancement of conductive inks and composites are viewed as shorter-term opportunities.In electronics, competition from silicon in semiconductors. Other competing technologies include sliver nanowires and carbon nanotubes as well as other 2D materials such as boron nitride, molybdenum disulfide, tungsten tungsten disulfide and germanane.

 

Graphene in Electronics and Energy

Global Silicon on Insulator Market

ELECTRONICS.CA PUBLICATIONS announces the availability of a new report entitled “Silicon on Insulator Market Technology – Global Forecast to 2020″. The global silicon-on-insulator market is expected to grow at a CAGR of 18.9% from 2014 to 2020. This growth is attributed to the growing smartphone and consumer electronics and the increasing trend of the Internet of Things. The geographic expansion in emerging markets and increasing applications of SOI devices are expected to offer lucrative opportunities for the SOI players in the next six years.

Silicon On Insulator (SOI) Market Size, 2013-2020 ($Million)

Silicon on Insulator has already revolutionized the consumer application industry. Various other SOI applications such as connected cars, consumer electronic products are also evolving and will further drive opportunities for many industry players across the large, complex Silicon on Insulator ecosystem. Huge R&D Investments and government funding in SOI research projects worldwide are driving the growth of the SOI market, especially in the U.S. (Americas), France (Europe), and China (Asia).

This report, based on the extensive research study on the Silicon on Insulator market, is aimed at identifying the major application verticals, where Silicon on Insulator is expected to bring about a game changing revolution in the years to come. The report covers several applications, namely- automotive, computing, entertainment & gaming, photonics, and telecom instruments. The major products that are made out of the SOI wafers are optical devices, RF devices, transistors, MEMS, image sensors, memory devices and others.

Projections with regards to the market size in terms of value have been provided till 2020 for the Silicon on Insulator and its sub-segment markets by application (Automotive, Computing & Mobile, Entertainment & Gaming, Photonics, and Telecom Instruments) and geography (Americas, Europe, APAC and RoW).

This report covers the overall dynamics of the entire Silicon on Insulator market, which includes drivers, restraints, and opportunities along with their impact in the current as well as the future scenario. A detailed analysis of the global SOI market, key current application trends, and emerging trends of Silicon on Insulator are presented in the report.

This report profiles all the major companies involved in the field of Silicon on Insulator such as Applied Material Inc. (U.S.), ARM Holding (U.K.), IBM Corp. (U.S.), Freescale Semiconductors (U.S.), Globalfoundries (U.S.), Shin-Etsu Chemical Co. Ltd. (Japan), Soitec SA (France), STMicroelectronics (Switzerland), SunEdison (U.S.) Synopsis Inc.(U.S.) Taiwan Semiconductor Manufacturing Corp. (Taiwan), and United Microchip Corp. (Taiwan).

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.  View the report: Silicon on Insulator Market Technology – Global Forecast to 2020.

 

 

Global Silicon on Insulator Market

Wireless Charging ICs Market Report

The First Edition analysis of the Wireless Charging Market is an in-depth analysis detailing the latest developments in this important emerging market. The wireless power charging IC market will see tremendous growth over the next five years, with a dollar market increasing from $284.3 million in 2015 to over $2.8 billion in 2020, a compounded annual growth rate (CAGR) of 58.7%. The wireless power charging market covered in this report is made up of both wireless charging receiver ICs and transmitter ICs. But the longer-term market growth is still uncertain.

“While wireless charging is rapidly gaining market share, its continued success and the final size of the wireless charging market is still to be determined,” stated Richard Ruiz, analyst and author of this report. “There are a number of significant factors that could derail this emerging market including the continued uncertainty of the standards environment, especially the on-going development of a new standard by IEEE and the uncertainty regarding the efficacy of wireless charging relative to energy efficiency standards such as the California Energy Commission (CEC), Level V, that mandates ac adapters meet a minimum efficiency of 85%. It remains to be seen if wireless charging technology can meet this requirement. For these and other reasons, wireless charging is not a ‘done deal’,” Ruiz concluded. The elimination of the need to maintain multiple external power supplies, one for each electronic device, has long been a goal for both the consumers and manufacturers of consumer electronics equipment and over the past several years there have been a number of developments moving the industry towards this goal. In the medium- and longer-terms, the differing growth rates for transmitters and receivers will have a significant impact on the opportunities for companies offering wireless charging. For example, in 2015, the receiver units market is over three times as large and by 2020 it is almost five times larger. This spread will continue to grow as both markets approach different saturation levels and different long-term growth rates.

Additional forecasts in this report include both low and medium power receiver and transmitter ICs for both Wireless Power Consortium Qi technology and A4WP technology. Driven by the large mobile phone market, over the forecast period the receiver IC market is projected to be dominated by Qi technology, while the transmitter IC market will have a higher percentage of A4WP technology. For the purpose of this report, the A4WP and PMA products have been combined.

Among the additional areas to watch are advances in IC technology, in particular advanced semiconductor developments which are moving towards circuits with dual-mode wireless power capability, components and materials, and advances in digital power technology. Also important to observe are a number of long-term alliances and partnerships as well as developments in standards and regulations, efficiency and standby power requirements and the clear long-term shift from first generation (tightly-coupled) to second-generation (flexibly-coupled) wireless power transfer technologies.

Wireless Charging ICs Market Report

This 106-page report contains over 45 tables, graphs and illustrations covering the wireless charging market, including a market share for key suppliers. The focus of this comprehensive analysis is to provide decision makers and manufacturers and operations with a detailed and insightful look at the current and future opportunities available in the wireless charger IC market. Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.

View the report: “Wireless Charging Technology: Receiver and Transmitter ICs Worldwide Forecasts“.

 

Wireless Charging ICs Market Report

Alternative Energy Technologies, Opportunities and Markets

ELECTRONICS.CA PUBLICATIONS announces the availability of a new report entitled “Semiconductors for Alternative Energy Technologies: Opportunities and Markets“. Economic conditions have had a dramatic impact on alternative energy.  When oil dropped to $40 a barrel, who cared about alternative energy? Shorted sighted but with the credit market crunch, who could get a loan to build solar plants anyway? Now oil is more than $110 a barrel.

The high price of oil in the past few years has been a catalyst for development in other alternative energy sources, not just solar.  Advances in wind, geothermal, and hydropower are reducing the cost of wind power to a point at which it is becoming competitive with traditional energy sources.  Nuclear power plants smaller than a garden shed and able to power 20,000 homes will be on sale within five years, say scientists at Los Alamos, the US government laboratory which developed the first atomic bomb.  Among these alternative energy sources, hydropower and nuclear have the lowest carbon footprint (carbon dioxide produced during operation).

World energy consumption is expected to increases from 472 quadrillion Btu in 2006 to 552 quadrillion Btu in 2015 and 678 quadrillion Btu in 2030—a total increase of 44 percent over the projection period. Total world energy use in 2030 is about 2 percent lower than projected in the International Energy Outlook 2008 (IEO2008), largely as the result of a slower overall rate of economic growth in this year’s reference case.

The current economic downturn dampens world demand for energy in the near term, as manufacturing and consumer demand for goods and services slow. IEO2009 assumes, however, that most nations will begin to return to trend growth within the next 12 to 24 months.

OECD member countries, for the most part, have the world’s most established energy infrastructures. In combination, they account for the largest share of current world energy consumption. The situation is expected to change over the projection period, however, with more rapid growth in energy demand in emerging non-OECD economies. In 2006, 51 percent of world energy consumption was in the OECD economies; but in 2030 their share falls to 41 percent in the reference case. OECD energy use grows slowly over the projection period, averaging 0.6 percent per year, as compared with 2.3 percent per year for the emerging non-OECD economies.

China and India are the fastest-growing non-OECD economies, and they will be key world energy consumers in the future. Since 1990, energy consumption as a share of total world energy use has increased significantly in both countries. China and India together accounted for about 10 percent of the world’s total energy consumption in 1990, but in 2006 their combined share was 19 percent. Strong economic growth in both countries continues over the projection period, with their combined energy use increasing nearly twofold and making up 28 percent of world energy consumption in 2030 in the reference case. In contrast, the U.S. share of total world energy consumption falls from 21 percent in 2006 to about 17 percent in 2030.

Non-OECD Asia shows the most robust growth of all the non-OECD regions, with energy use rising by 104 percent from 2006 to 2030 (Figure 13). Energy consumption in other non-OECD regions also grows strongly over the projection period, with projected increases of around 60 percent for the Middle East and for Central and South America and 50 percent for Africa. A smaller increase, about 25 percent, is expected for non-OECD Europe and Eurasia (including Russia and the other former Soviet Republics), as declining population and substantial gains in energy efficiency result from the replacement of inefficient Soviet-era capital equipment.

SOLAR ENERGY

Compared to other renewable energy technologies, solar power’s benefits include:

• Environmental Advantage: Solar power is one of the most benign electric generation resources. Solar cells generate electricity without air or water emissions, noise, vibration, habitat impact or waste generation.


• Fuel Risk Advantage: Unlike fossil and nuclear fuels, solar energy has no risk of fuel price volatility or delivery risk. Although there is variability in the amount and timing of sunlight over the day, season and year, a properly sized and configured system can be designed to be highly reliable while providing a long-term, fixed price electric supply.


• Location Advantage: Unlike other renewable resources such as hydroelectric and wind power, solar power is generally located at a customer site due to the universal availability of sunlight. As a result, solar power limits the expense of, and energy losses associated with, transmission and distribution from large-scale electric plants to the end users. For most residential consumers seeking an environmentally friendly power alternative, solar power is the only viable choice because it can be located in urban and suburban environments.


• Retail Rate Benchmark Advantage: Unlike biomass, geothermal, hydroelectric and wind power generation, which are location-dependent and sell primarily to the wholesale market, solar power competes with retail electric rates as it is customer-sited and supplements a customer’s electricity purchased at retail rates from the utility network.


• Peak Energy Generation Advantage: Solar power is well-suited to match peak energy needs as maximum sunlight hours generally correspond to typical peak demand periods when electricity prices are at their highest. These characteristics increase the value of solar power as compared to other renewable resources that do not align with peak demand periods.


• Modularity: Solar power products can be deployed in many sizes and configurations to meet the specific needs of the customer.


• Reliability: With no moving parts or regular required maintenance, solar power systems are among the most reliable forms of electricity generation.

Weakness includes:

• The global economic crises will temper alternative energy sales and earnings growth.


• The immediate concern over economic weakness likely takes the short-term focus off progress toward a new energy policy.


• Continued weakness in the debt and equity markets, for as long as it lasts, will raise costs of capital for firms in this emerging sector, and may prevent project financing, working capital requirements, and new research and development. Federal funding for a new energy policy will largely dry up.

WIND ENERGY

There are a range of advantages and disadvantages of wind energy to look at, including the many problems associated with wind turbines.

Advantages:

• Wind energy is friendly to the surrounding environment, as no fossil fuels are burnt to generate electricity from wind energy.


• Wind turbines take up less space than the average power station. Windmills only have to occupy a few square meters for the base; this allows the land around the turbine to be used for many purposes, for example agriculture.


• Newer technologies are making the extraction of wind energy much more efficient. The wind is free, and we are able to cash in on this free source of energy.


• Wind turbines are a great resource to generate energy in remote locations, such as mountain communities and remote countryside. Wind turbines can be a range of different sizes in order to support varying population levels.


• Another advantage of wind energy is that when combined with solar electricity, this energy source is great for developed and developing countries to provide a steady, reliable supply of electricity.

Disadvantages:

• The main disadvantage regarding wind power is down to the winds unreliability factor. In many areas, the winds strength is too low to support a wind turbine or wind farm, and this is where the use of solar power or geothermal power could be great alternatives.


• Wind turbines generally produce allot less electricity than the average fossil fuelled power station, requiring multiple wind turbines to be built in order to make an impact.


• Wind turbine construction can be very expensive and costly to surrounding wildlife during the build process.


• The noise pollution from commercial wind turbines is sometimes similar to a small jet engine. This is fine if you live miles away, where you will hardly notice the noise, but what if you live within a few hundred meters of a turbine? This is a major disadvantage.


• Protests and/or petitions usually confront any proposed wind farm development. People feel the countryside should be left in tact for everyone to enjoy its beauty.

FUEL CELLS

Fuel cells are very useful as power sources in remote locations, such as spacecraft, remote weather stations, large parks, rural locations, and in certain military applications. A fuel cell system running on hydrogen can be compact and lightweight, and have no major moving parts. Because fuel cells have no moving parts and do not involve combustion, in ideal conditions they can achieve up to 99.9999% reliability. This equates to around one minute of down time in a two year period.

Some additional advantages of the fuel cells can be summarized as  follows:

• High efficiency conversion. Fuel cells convert chemical energy directly into electricity without the combustion process. As a result, a fuel cell is not governed by thermodynamic laws, such as the Carnot efficiency associated with heat engines, currently used for power generation. Fuel cells can achieve high efficiencies in energy conversion terms, especially where the waste heat from the cell is utilized in cogeneration situation.


• High power density. A high power density allows fuel cells to be relatively compact source of electric power, beneficial in application with space constraints. In a fuel cell system, the fuel cell itself is nearly dwarfed by other components of the system such as the fuel reformer and power inverter


• Quiet operation. Fuel cells, due to their nature of operation, are extremely quiet in operation. This allows fuel cells to be used in residential or built-up areas where the noise pollution is undesirable.

Disadvantages

• The only disadvantage of the fuel cells associated with the cost. The two basic reasons are High costs compared to other energy systems technology and Operation requires a replenishable fuel supply.

NiMH Batteries

A nickel-metal hydride cell, abbreviated NiMH, is a type of secondary electrochemical cell similar to Nickel Hydrogen cell. The NiMH battery uses a hydrogen-absorbing alloy for the negative electrode instead of cadmium. As in NiCd cells, the positive electrode is nickel oxyhydroxide (NiOOH).

Applications of NiMH Electric vehicle batteries includes all-electric plug-in vehicles such as the General Motors EV1, Honda EV Plus, Ford Ranger EV and Vectrix scooter. Hybrid vehicles such as the Toyota Prius, Honda Insight, Ford Escape Hybrid, and Honda Civic Hybrid also use them. NiMH technology is used extensively in rechargeable batteries for consumer electronics, and it will also be used on the Alstom Citadis low floor tram ordered for Nice, France; as well as the humanoid prototype robot ASIMO designed by Honda.

Advantages

• 30 – 40 percent higher capacity over a standard NiCd. The NiMH has potential for yet higher energy densities.


• Less prone to memory than the NiCd. Periodic exercise cycles are required less often.


• Simple storage and transportation — transportation conditions are not subject to regulatory control.


• Environmentally friendly — contains only mild toxins; profitable for recycling.

Disadvantages

• Limited service life — if repeatedly deep cycled, especially at high load currents, the performance starts to deteriorate after 200 to 300 cycles. Shallow rather than deep discharge cycles are preferred.


• Limited discharge current — although a NiMH battery is capable of delivering high discharge currents, repeated discharges with high load currents reduces the battery’s cycle life. Best results are achieved with load currents of 0.2C to 0.5C (one-fifth to one-half of the rated capacity).


• More complex charge algorithm needed — the NiMH generates more heat during charge and requires a longer charge time than the NiCd. The trickle charge is critical and must be controlled carefully.


• High self-discharge — the NiMH has about 50 percent higher selfdischarge compared to the NiCd. New chemical additives improve the self-discharge but at the expense of lower energy density.


• Performance degrades if stored at elevated temperatures — the NiMH should be stored in a cool place and at a state-of-charge of about 40 percent.


• High maintenance — battery requires regular full discharge to prevent crystalline formation.


• About 20 percent more expensive than NiCd — NiMH batteries designed for high current draw are more expensive than the regular version.

Li-ion Polymer Batteries

Lithium-ion polymer batteries, polymer lithium ion, or more commonly lithium polymer batteries are rechargeable batteries that have technologically evolved from lithium-ion batteries. Ultimately, the lithium-salt electrolyte is not held in an organic solvent as in the lithium-ion design, but in a solid polymer composite such as polyethylene oxide or polyacrylonitrile.

Li-poly batteries are gaining ground in smartphones and notebook computers. They can be found in small digital music devices such as iPods and other MP3 players as well as gaming equipment like Sony’s Playstation 3 wireless controllers.

These batteries may also power the next generation of battery electric vehicles. The cost of an electric car of this type is prohibitive, but proponents argue that with increased production, the cost of Li-poly batteries will go down.

Advantages

• Very low profile — batteries that resemble the profile of a credit card are feasible.


• Flexible form factor — manufacturers are not bound by standard cell formats. With high volume, any reasonable size can be produced economically.


• Light weight – gelled rather than liquid electrolytes enable simplified packaging, in some cases eliminating the metal shell.


• Improved safety — more resistant to overcharge; less chance for electrolyte leakage.

Disadvantages

• Lower energy density and decreased cycle count compared to Li-ion — potential for improvements exist.


• Expensive to manufacture — once mass-produced, the Li-ion polymer has the potential for lower cost. Reduced control circuit offsets higher manufacturing costs.

GEOTHERMAL ENERGY

Geothermal heat pumps have several advantages and disadvantages. Which geothermal system is right for a given installation, or even whether to use a geothermal system, depends on the circumstances of that particular installation.

Geothermal energy is a proven resource for direct heat and power generation. In over 30 countries geothermal resources provide directly used heat capacity of 12,000 MW and electric power generation capacity of over 8,000 MW.

Advantages

• In both commercial and residential installations, geothermal heat pump systems typically have lower maintenance costs than conventional systems as all equipment is installed inside the building or underground. This means that there is no outside equipment exposed to weather and vandalism. All refrigerant systems are sealed, similar to household refrigerators.


• Geothermal systems are very flexible. They can be easily and inexpensively subdivided or expanded to fit building remodeling or additions. They are particularly well-suited to “tenant finish” installations.


• In commercial installations, systems can save money by recovering excess heat from building interior zones and moving it to the perimeter of the building. They can also save money by allowing management to isolate and shut down unoccupied areas of the building.


• Refrigerant Loop geothermal systems have several advantages over other geothermal systems. They are potentially more efficient than water loop systems. They require fewer feet of buried piping than other geothermal systems, have no freeze problems, and better heat transfer.

Disadvantages

• Geothermal systems tend to have a somewhat higher first cost than conventional systems. Open-loop systems have more potential problems than either conventional systems or closed-loop geothermal systems because they bring outside water into the unit. This can lead to clogging, mineral deposits, and corrosion in the system.


• Open-loop systems require a large supply of clean water in order to be cost effective. This often limits their use to coastal areas, and areas adjacent to lakes, rivers, streams, etc. In addition, there must be an acceptable method of returning the used water to the environment. This may be limited not only by environmental factors (such as no place to dump that much water), but also by local and state regulations.


• Many closed-loop systems use an antifreeze solution to keep the loop water from freezing in cold temperature conditions.


• Most antifreeze solutions have very low toxicity, but many produce CFCs and HCFCs, which add to environmental concerns. In addition, some antifreeze solutions increase fluid viscosity making the system work harder and adding to the cost of pumping.


• Refrigerant Loop systems have several disadvantages, including: Environmental issues related to the system’s use of refrigerant, Corrosion issues since they use copper piping which needs anodic protection, and the need to maintain refrigerant temperatures within certain limits to keep from freezing or baking the ground, Difficulty in finding and fixing a refrigerant loop leak, should one occur.


• Since accessibility to terminal units is important in geothermal systems, architects and mechanical and structural designers must carefully coordinate their work.


• Each unit requires both electrical and plumbing service.


• Duct systems must be installed to bring outside air to each space.


• Secondary or backup heat sources are required in cooler climates.


• It’s only in recent years, in the light of climate change, that the issue of nuclear power is being debated once again because of its nature: it emits virtually no greenhouse gases. Not only that, but the fuel for it, uranium, can be found in far more stable regions of the world than oil. So, what are the advantages and disadvantages of nuclear power?

NUCLEAR POWER

There were 439 operating nuclear power plants and, together, they provided about 14 percent of the world’s electricity at the end of 2009. Of these 31 countries, some depend more on nuclear power than others. For instance, in France about 77 percent of the country’s electricity comes from nuclear power. Lithuania comes in second, with an impressive 65 percent. In the United States, 104 nuclear power plants supply 20 percent of the electricity overall, with some states benefiting more than others.

Power plants that depend on atomic energy don’t operate that differently from a typical coal-burning power plant. Both heat water into pressurized steam, which drives a turbine generator. The key difference between the two plants is the method of heating the water. While older plants burn fossil fuels, nuclear plants depend on the heat that occurs during nuclear fission, when one atom splits into two.

 Advantages

• Efficient: Nuclear plants can produce an awful let of electricity, up to about 2GW, which is comparable to coal plants.


• Reliable: There is no need to worry about interruptions to the power supply: as long as there is uranium, there will be power. This is a stark contrast to most renewable energies which depend on the activity of the weather.


• Clean: I’m using this term strictly to refer to the greenhouse gas emissions of a nuclear plant. There are some greenhouse gas emissions associated with the life cycle of uranium, as gases are emitted as it is mined and transported etc. However this is significantly less than the emissions associated with the burning of fossil fuels. Essentially, nuclear power would be “carbon-zero” if the uranium were mined and transported in a more efficient way. There are issues with radioactive waste, however.


• Supply: Twenty-four percent of uranium resources are in Australia, and 9% in Canada .

Disadvantages

• Waste: High level radioactive waste is very dangerous. It lasts for tens of thousands of years before decaying to safe levels. If there is to be a “nuclear renaissance”, a sophisticated method of storing the waste for this period of time must be designed.


• Proliferation: Some forms of nuclear reactor, known as “breeder” reactors produce plutonium, which can be used to make nuclear weapons. There are other reactors which do not have this problem, but it is another issue which must be addressed before the possibility of a nuclear future can be taken seriously.


• Terrorism: While the chances of a modern reactor exploding like Chernobyl are near zero, it is quite possible for intervention to have quite horrific results. Nuclear plants would be very tempting targets to anyone wanting to disrupt the power supply and devastate an entire region in one foul swoop.


• Cost: Nuclear plants are very expensive to run. I’m not an economist, but I believe nuclear plants are, like most other things, cheaper in bulk. Most of the cost comes from the initial building of the plant; the running costs are comparatively low.

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.View the report: Semiconductors for Alternative Energy Technologies: Opportunities and Markets.

 

 

Alternative Energy Technologies, Opportunities and Markets

Wireless Charging ICs Market Report

The First Edition analysis of the Wireless Charging Market is an in-depth analysis detailing the latest developments in this important emerging market. The wireless power charging IC market will see tremendous growth over the next five years, with a dollar market increasing from $284.3 million in 2015 to over $2.8 billion in 2020, a compounded annual growth rate (CAGR) of 58.7%. The wireless power charging market covered in this report is made up of both wireless charging receiver ICs and transmitter ICs. But the longer-term market growth is still uncertain.

“While wireless charging is rapidly gaining market share, its continued success and the final size of the wireless charging market is still to be determined,” stated Richard Ruiz, analyst and author of this report. “There are a number of significant factors that could derail this emerging market including the continued uncertainty of the standards environment, especially the on-going development of a new standard by IEEE and the uncertainty regarding the efficacy of wireless charging relative to energy efficiency standards such as the California Energy Commission (CEC), Level V, that mandates ac adapters meet a minimum efficiency of 85%. It remains to be seen if wireless charging technology can meet this requirement. For these and other reasons, wireless charging is not a ‘done deal’,” Ruiz concluded. The elimination of the need to maintain multiple external power supplies, one for each electronic device, has long been a goal for both the consumers and manufacturers of consumer electronics equipment and over the past several years there have been a number of developments moving the industry towards this goal. In the medium- and longer-terms, the differing growth rates for transmitters and receivers will have a significant impact on the opportunities for companies offering wireless charging. For example, in 2015, the receiver units market is over three times as large and by 2020 it is almost five times larger. This spread will continue to grow as both markets approach different saturation levels and different long-term growth rates.

Additional forecasts in this report include both low and medium power receiver and transmitter ICs for both Wireless Power Consortium Qi technology and A4WP technology. Driven by the large mobile phone market, over the forecast period the receiver IC market is projected to be dominated by Qi technology, while the transmitter IC market will have a higher percentage of A4WP technology. For the purpose of this report, the A4WP and PMA products have been combined.

Among the additional areas to watch are advances in IC technology, in particular advanced semiconductor developments which are moving towards circuits with dual-mode wireless power capability, components and materials, and advances in digital power technology. Also important to observe are a number of long-term alliances and partnerships as well as developments in standards and regulations, efficiency and standby power requirements and the clear long-term shift from first generation (tightly-coupled) to second-generation (flexibly-coupled) wireless power transfer technologies.

Wireless Charging ICs Market Report

This 106-page report contains over 45 tables, graphs and illustrations covering the wireless charging market, including a market share for key suppliers. The focus of this comprehensive analysis is to provide decision makers and manufacturers and operations with a detailed and insightful look at the current and future opportunities available in the wireless charger IC market. Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications’ web site.

View the report: “Wireless Charging Technology: Receiver and Transmitter ICs Worldwide Forecasts“.

 

Wireless Charging ICs Market Report