Roland - AP-7 Jet Phaser

"... Most people know Roland Corporation for one of two reasons: One; for its amazing synthesizers and drum machines spanning several decades. Two; as the parent company of Boss, the biggest effects brand on the planet. Some pedal enthusiasts are unaware that Roland itself made pedals—good ones! 

For a time in the ‘70s, Boss and Roland intermingled with one another, with Roland choosing to slap the Boss name on certain effects (CE-1, DM-1, DB-5) and its own name on the rest, even though some of this gear shared similar enclosures, and even though some pedals were branded as one company, but as the evolution of the other company’s innovations (such as the Boss CE-1 being a standalone Roland Jazz Chorus effect). I’m here to talk about perhaps the most unsung vintage Roland piece; the AP-7 Jet Phaser.

For reasons unbeknownst, Roland excelled at ensconcing a stellar (oftentimes dirt) circuit within the confines of another, larger pedal and releasing the non-dirt part as a standalone model. One such example is the AD-50 Double Beat fuzz wah, containing an absolutely disgusting fuzz circuit yet releasing the AW-10 Wah Beat. 

The Jet Phaser is just such a circuit, combining phaser with, well . . . “Jet.” Much like the fuzz section from the Double Beat is—by virtue of naming conventions—a form of “beat,” “Jet” refers to an absolutely screaming distortion effect that sits in front of a juicy phaser circuit—the same one found within the AP-2 Phaser. 

This highly-adapable Jet circuit transforms the mild mannered phaser into a pulverizing throb, jumping out of the mix with some serious propulsion. Larry Graham of Sly and the Family Stone famously used one, as did Ernie Isley of the famous brothers, on “Who’s That Lady?.” In fact, that thick, viscous fuzz you hear on that cut’s leads is the characteristic Jet sound, and has been one of the most quietly sought-after lead tones in history. 

The Jet side of the circuit has no analog in today’s pedal market, it’s a curious piece of circuit, featuring equal parts discrete semiconductors and monolithic op-amps. A rotary switch on the face of the unit selects between four forms of Jet and two of Phase. Switching between the Jet settings yields different tonal compounds, cycling between gain stages, a notch filter and more. All of this is controlled by one master Jet knob, which offers varying intensity rather than a simple volume. On all Jet settings, the phaser is integrated; no configuration offers an isolated Jet section.

On the phaser side, we have an eight-stage FET-based phaser with a Resonance control. As far as vintage offerings are concerned, eight stages—the MXR phaser line of the 45, 90 and 100 offers two, four and six stages respectively—is quite a feat. With the added Resonance control, the phaser section can actually give your amp a little bit of a nudge at the peaks.

Much like the Maestro PS-1A (and B), the Jet Phaser offers a Fast/Slow footswitch that comes in the form of . . . an actual footswitch instead of clunky organ rockers. Maestro’s model offers ramping between speeds if you switch it on the fly; difficult if you’re not wearing pointy heels or cowboy boots, so the ramping feature wasn’t a tactfully expressive performance tool. The Jet Phaser solves all this by offering a Fast/Slow switch and letting you set your slow speed with a knob (the “Fast” setting is just this same knob turned all the way up). When switching between the two speeds, the rate gradually descends to the desired level.

Finally, I would be remiss if I didn’t include my all-time favorite effects-adjacent video—Larry Graham absolutely shredding on a Jet Phaser. ..."

cred: catalinbread.com/kulas-cabinet/roland-ap-7-jet-phaser

Global top 13 companies accounted for 66% of Total Frozen Spring Roll market(qyresearch, 2021)

The table below details the Discrete Manufacturing ERP revenue and market share of major players, from 2016 to 2021. The data for 2021 is an estimate, based on the historical figures and the data we interviewed this year.

Major players in the market are identified through secondary research and their market revenues are determined through primary and secondary research. Secondary research includes the research of the annual financial reports of the top companies; while primary research includes extensive interviews of key opinion leaders and industry experts such as experienced front-line staffs, directors, CEOs and marketing executives. The percentage splits, market shares, growth rates and breakdowns of the product markets are determined through secondary sources and verified through the primary sources.

According to the new market research report “Global Discrete Manufacturing ERP Market Report 2023-2029”, published by QYResearch, the global Discrete Manufacturing ERP market size is projected to reach USD 9.78 billion by 2029, at a CAGR of 10.6% during the forecast period.

Figure.   Global Frozen Spring Roll Market Size (US$ Mn), 2018-2029

Figure.   Global Frozen Spring Roll Top 13 Players Ranking and Market Share（Based on data of 2021, Continually updated）

The global key manufacturers of Discrete Manufacturing ERP include Visibility, Global Shop Solutions, SYSPRO, ECi Software Solutions, abas Software AG, IFS AB, QAD Inc, Infor, abas Software AG, ECi Software Solutions, etc. In 2021, the global top five players had a share approximately 66.0% in terms of revenue.

About QYResearch

QYResearch founded in California, USA in 2007.It is a leading global market research and consulting company. With over 16 years’ experience and professional research team in various cities over the world QY Research focuses on management consulting, database and seminar services, IPO consulting, industry chain research and customized research to help our clients in providing non-linear revenue model and make them successful. We are globally recognized for our expansive portfolio of services, good corporate citizenship, and our strong commitment to sustainability. Up to now, we have cooperated with more than 60,000 clients across five continents. Let’s work closely with you and build a bold and better future.

QYResearch is a world-renowned large-scale consulting company. The industry covers various high-tech industry chain market segments, spanning the semiconductor industry chain (semiconductor equipment and parts, semiconductor materials, ICs, Foundry, packaging and testing, discrete devices, sensors, optoelectronic devices), photovoltaic industry chain (equipment, cells, modules, auxiliary material brackets, inverters, power station terminals), new energy automobile industry chain (batteries and materials, auto parts, batteries, motors, electronic control, automotive semiconductors, etc.), communication industry chain (communication system equipment, terminal equipment, electronic components, RF front-end, optical modules, 4G/5G/6G, broadband, IoT, digital economy, AI), advanced materials industry Chain (metal materials, polymer materials, ceramic materials, nano materials, etc.), machinery manufacturing industry chain (CNC machine tools, construction machinery, electrical machinery, 3C automation, industrial robots, lasers, industrial control, drones), food, beverages and pharmaceuticals, medical equipment, agriculture, etc.

Field Programmable Gate Array (FPGA) Market - Forecast(2024 - 2030)

The FPGA market was valued at USD 4.79 Billion in 2017 and is anticipated to grow at a CAGR of 8.5% during 2017 and 2023. The growing demand for advanced driver-assistance systems (ADAS), the growth of IoT and reduction in time-to-market are the key driving factors for the FPGA market. Owing to benefits such as increasing the performance, early time to market, replacing glue logic, reducing number of PCB spins, and reducing number of parts of PCB, field programmable gate arrays (FPGA’s) are being used in many CPU’s. Industrial networking, industrial motor control, industrial control applications, machine vision, video surveillance make use of different families of FPGA’s.

North America is the leading market for field programmable gate arrays with U.S. leading the charge followed by Europe. North America region is forecast to have highest growth in the next few years due to growing adoption of field programmable gate arrays.

What is Field Programmable Gate Arrays?

Field Programmable Gate Arrays (FPGAs) are semiconductor devices. The lookup table (LUT) is the basic block in every FPGA. Different FPGAs use variable sized LUTs. A lookup table is logically equivalent to a RAM with the inputs being the address select lines and can have multiple outputs in order to get two Boolean functions of the same inputs thus doubling the number of configuration bits. FPGAs can be reprogrammed to desired application or functionality requirements after manufacturing. This differentiates FPGAs from Application Specific Integrated Circuits (ASICs) although they help in ASIC designing itself, which are custom manufactured for specific design tasks. 

In a single integrated circuit (IC) chip of FPGA, millions of logic gates can be incorporated. Hence, a single FPGA can replace thousands of discrete components. FPGAs are an ideal fit for many different markets due to their programmability. Ever-changing technology combined with introduction of new product portfolio is the major drivers for this industry.

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What are the major applications for Field Programmable Gate Arrays?

FPGA applications are found in Industrial, Medical, Scientific Instruments, security systems, Video & Image Processing, Wired Communications, Wireless Communications, Aerospace and Defense, Medical Electronics, Audio, Automotive, Broadcast, Consumer Electronics, Distributed Monetary Systems, Data and Computer Centers and many more verticals.

Particularly in the fields of computer hardware emulation, integrating multiple SPLDs, voice recognition, cryptography, filtering and communication encoding,  digital signal processing, bioinformatics, device controllers, software-defined radio, random logic, ASIC prototyping, medical imaging, or any other electronic processing FGPAs are implied because of their capability of being programmable according to requirement. FPGAs have gained popularity over the past decade because they are useful for a wide range of applications.

FPGAs are implied for those applications in particular where the production volume is small. For low-volume applications, the leading companies pay hardware costs per unit. The new performance dynamics and cost have extended the range of viable applications these days.

Market Research and Market Trends of Field Programmable Gate Array (FPGA) Ecosystem

FPGA As Cloud Server: IoT devices usually have limited processing power, memory size and bandwidth. The developers offer interfaces through compilers, tools, and frameworks. This creates effectiveness for the customer base and creates strong cloud products with increased efficiency which also included new machine learning techniques, Artificial Intelligence and big data analysis all in one platform. Web Service Companies are working to offer FPGAs in Elastic Compute Cloud (EC2) cloud environment. 

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Artificial Intelligence: As an order of higher magnitude performance per Watt than commercial FPGAs and (Graphical Processing Unit) GPUs in SOC search giant offers TPUs (Google’s Tensor Processing Units). AI demands for higher performance, less time, larger computation with more power proficient for deep neural networks. Deep neural network power-up the high-end devices. Google revealed that the accelerators (FGPAs) were used for the Alpha GO systems which is a computer developed by Google DeepMind that plays the board game Go.  CEA also offers an ultra-low power programmable accelerator called P-Neuro.

Photonic Networks for Hardware Accelerators: Hardware Accelerators normally need high bandwidth, low latency, and energy efficiency. The high performance computing system has critical performance which is shifted from the microprocessors to the communications infrastructure. Optical interconnects are able to address the bandwidth scalability challenges of future computing systems, by exploiting the parallel nature and capacity of wavelength division multiplexing (WDM). The multi-casted network uniquely exploits the parallelism of WDM to serve as an initial validation for architecture. Two FPGA boarded systems emulate the CPU and hardware accelerator nodes. Here FPGA transceivers implement and follow a phase-encoder header network protocol. The output of each port is individually controlled using a bitwise XNOR of port’s control signal. Optical packets are send through the network and execute switch and multicasting of two receive nodes with most reduced error

Low Power and High Data Rate FPGA: “Microsemi” FPGAs provides a non-volatile FPGA having 12.7 GB/s transceiver and lower poor consumption less than 90mW at 10 GB/s. It manufactured using a 28nm silicon-oxide-nitride-oxide-silicon nonvolatile process on standard CMOS technology. By this they address cyber security threats and deep submicron single event upsets in configuration memory on SRAM-based FPGA. These transceivers use cynical I/O gearing logic for DDR memory and LVDS. Cryptography research provides differential power analysis protection technology, an integrated physical unclonable function and 56 kilobyte of secure embedded non-volatile memory, the built-in tamper detectors parts and counter measures.

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Speeds up FPGA-in-the-loop verification: HDL Verifier is used to speed up FPGA-in-the-loop (FIL) verification. Faster communication between the FPGA board and higher clock frequency is stimulated by the FIL capabilities. This would increase the complexity of signal processing, control system algorithms and vision processing. For validation of the design in the system context simulate hardware implementation on an FPGA board. HDL Verifier automates the setup and connection of MATLAB and Simulink test environments to designs running on FPGA development boards. The R2016b has been released that allows engineers to specify a custom frequency for their FPGA system clock with clock rates up to five times faster than previously possible with FIL. This improves faster run-time. From MATLAB and Simulink is an easy way to validate hardware design within the algorithm development environment

Xilinx Unveils Revolutionary Adaptable Computing Product Category: Xilinx, Inc. which is leader in FGPAs, has recently announced a new product category which is named as Adaptive Compute Acceleration Platform (ACAP) and has the capabilities far beyond of an FPGA. An ACAP is a highly integrated multi-core heterogeneous compute platform that can be changed at the hardware level to adapt to the needs of a wide range of applications and workloads. ACAP has the capability of dynamic adaption during operation which enables it to deliver higher performance per-watt levels that is unmatched by CPUs or GPUs.

Lattice Releases Next-Generation FPGA Software for Development of Broad Market Low Power Embedded Applications: Lattice Semiconductor, launched its FPGA software recently. Lattice Radiant targeted for the development of broad market low power embedded applications. Device’s application expands significantly across various market segments including mobile, consumer, industrial, and automotive due to is rich set of features and ease-of-use, Lattice Radiant software’s support for iCE40 Ultra plus FPGAs. ICE40 Ultra Plus devices are the world’s smallest FPGAs with enhanced memory and DSPs to enable always on, distributed processing. The Lattice Radiant software is available for free download.

Who are the Major Players in market?

The companies referred in the market research report include Intel Inc, Microsemi, Lattice Semiconductor, Xilinx, Atmel, Quick Logic Corp., Red Pitaya, Mercury Computer, Nallatech Inc., Achronix Semiconductor Corporation, Acromag Inc., Actel Corp., Altera Corp.

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The report incorporates in-depth assessment of the competitive landscape, product market sizing, product benchmarking, market trends, product developments, financial analysis, strategic analysis and so on to gauge the impact forces and potential opportunities of the market. Apart from this the report also includes a study of major developments in the market such as product launches, agreements, acquisitions, collaborations, mergers and so on to comprehend the prevailing market dynamics at present and its impact during the forecast period 2017-2023.

All our reports are customizable to your company needs to a certain extent, we do provide 20 free consulting hours along with purchase of each report, and this will allow you to request any additional data to customize the report to your needs.

Key Takeaways from this Report

Evaluate market potential through analyzing growth rates (CAGR %), Volume (Units) and Value ($M) data given at country level – for product types, end use applications and by different industry verticals.

Understand the different dynamics influencing the market – key driving factors, challenges and hidden opportunities.

Get in-depth insights on your competitor performance – market shares, strategies, financial benchmarking, product benchmarking, SWOT and more.

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Evaluate the supply-demand gaps, import-export statistics and regulatory landscape for more than top 20 countries globally for the market. 

Report shows that global semiconductor manufacturing is improving

The global semiconductor manufacturing industry in the first quarter of 2024 showed signs of improvement with an uptick in electronic sales, stabilizing inventories and an increase in installed wafer fab capacity, SEMI announced today in its Q1 2024 publication of the Semiconductor Manufacturing Monitor (SMM) Report, prepared in partnership with TechInsights. Stronger industry growth is expected in the second half of the year. In Q1 2024, electronic sales rose 1% year-over-year (YoY), with Q2 2024 forecast to register a 5% YoY increase. IC sales posted robust 22% YoY growth in Q1 2024 and are expected to surge 21% in Q2 2024 as shipments of high-performance computing (HPC) chips increase and memory pricing continues to improve. IC inventory levels stabilized in Q1 2024 and are expected to improve this quarter. Installed wafer fab capacity continues to increase and is projected to exceed 40 million wafers per quarter (in 300mm wafer equivalent), rising 1.2% in Q1 2024 with an expected 1.4% uptick in Q2 2024. China continues to log the highest capacity growth among all regions. However, fab utilization rates, particularly for mature nodes, remain a concern with little signs of recovery expected in the first half of 2024. Memory utilization rates were lower than expected in Q1 2024 due to disciplined supply control. In line with fab utilization trends, semiconductor capital expenditures remain conservative. After falling 17% YoY in Q4 2023, capital expenditures continued to pull back 11% in Q1 2024 before eking out an expected 0.7% gain in Q2 2024. Sequentially in Q2 2024, the trend is turning positive with an expected 8% increase in memory-related capital expenditures as they see slightly stronger growth than non-memory segments. Total IC Inventory Versus Utilization IC Sales "Demand in some semiconductor segments is recovering, but the pace of recovery is uneven," said Clark Tseng, Senior Director of Market Intelligence at SEMI. "AI chips and high-bandwidth memory are currently among devices in the highest demand, leading to increased investment and capacity expansion in these areas. However, the impact of AI chips on IC shipment growth remains limited due to their reliance on a small number of key suppliers." "Semiconductor demand in the first half of 2024 is mixed, with memory and logic rebounding due to surging generative AI demand," said Boris Metodiev, Director of Market Analysis at TechInsights. "However, analog, discrete, and optoelectronics have experienced a slight correction due to the slow recovery of the consumer market coupled with a pullback in demand from the automotive and industrial markets." "A full-on recovery is likely to take hold in the second half of the year with the projected boost in consumer demand by AI's expansion to the edge," Metodiev said. "Additionally, the automotive and industrial markets are expected to return to growth in the latter part of the year as interest rates fall – providing consumers more purchasing power – and inventory declines." The Semiconductor Manufacturing Monitor (SMM) report provides end-to-end data on the worldwide semiconductor manufacturing industry. The report highlights key trends based on industry indicators including capital equipment, fab capacity, and semiconductor and electronics sales, and includes a capital equipment market forecast. The SMM report also contains two years of quarterly data and a one-quarter outlook for the semiconductor manufacturing supply chain including leading IDM, fabless, foundry, and OSAT companies. An SMM subscription includes quarterly reports. Download a sample Semiconductor Manufacturing Monitor report.  Read the full article

Impact of Global Events on the Semiconductor Supply Chain

Originally Published on: SpendEdge |Global Events: Impact on the Semiconductor Supply Chain

Semiconductor Market: Industry Size and Overview

Semiconductors are indispensable in modern electronics, encompassing smartphones, laptops, vehicles, and medical equipment. With microprocessors and memory units as essential components, the global semiconductor market reached a valuation of around USD 618 billion in 2022, as reported by Semiconductor Equipment and Materials International (SEMI). Projections suggest this figure will exceed USD 1 trillion by 2030. Initially propelled by smartphones and computers, the surge in chip demand has expanded to include automobiles, IoT devices, and emerging technologies like AI and blockchain. Despite representing a small fraction of GDP, semiconductors significantly impact approximately 12 percent of GDP due to their extensive use in production processes. The recent semiconductor shortage, resulting in an estimated USD 240 billion reduction in the U.S. GDP in 2021, particularly affected industries such as automotive, emphasizing the critical role of semiconductors in global economic activities.

#SemiconductorIndustry #EconomicImpact

Overview of the Semiconductor Industry Value Chain

The semiconductor industry operates within a complex global supply chain, involving numerous processes to convert inputs into outputs. Integrated circuit (IC) chips, vital to modern technology, undergo a production process spanning four to six months and over 500 discrete stages. Inputs for a typical IC chip traverse more than 70 international borders before reaching consumers, highlighting the extensive nature of the semiconductor supply chain. Leading chip sellers maintain expansive supplier networks globally, with some possessing unique technological capabilities. Policymakers must understand the global semiconductor manufacturing landscape to effectively navigate shifting supply chains.

#SupplyChainComplexity #GlobalManufacturing

Challenges in the Semiconductor Supply Chain

Complexity and Vulnerability to Disruptions:

The increasing intricacy of the semiconductor supply chain renders it vulnerable to disruptions that can cascade throughout the system. Natural disasters such as Japan’s 2011 earthquake and the COVID-19 pandemic in 2020 have underscored this fragility, leading to chip shortages across various industries, notably impacting automotive manufacturing.

Geopolitical Tensions and Concentrated Manufacturing:

Concentration of semiconductor manufacturing in key regions like Asia exposes the supply chain to geopolitical tensions and trade disputes. Recent trade restrictions imposed by the United States have raised concerns about disruptions in material flows, impacting global semiconductor production and distribution.

#SupplyChainDisruptions #GeopoliticalRisks

Imbalances in Supply and Demand:

Manufacturing capacity constraints and fluctuations in demand contribute to shortages in the semiconductor supply chain. Industries such as automotive and medical devices face delays in product delivery, highlighting the criticality of semiconductor supply chain resilience.

Custom Specifications and Inventory Management:

Semiconductors designed for diverse applications pose challenges in manufacturing complexity and inventory management. Companies must strike a balance between customization needs and supply chain optimization to effectively respond to market fluctuations.

#SupplyDemandImbalances #InventoryManagementChallenges

The Complexity of the Global Supply Chain:

Semiconductor manufacturing relies on a complex global network involving numerous countries and companies. Multiple stages, from raw material supply to sales, require international divisions of labor, amplifying the intricacies of the semiconductor supply chain.

#GlobalSupplyChain #MarketDynamics

How SpendEdge Can Assist with the Semiconductor Supply Chain

SpendEdge offers three key solutions:

Supply Chain Updates: Providing real-time insights and risk notifications to optimize cost-cutting opportunities and mitigate uncertainties.

Supply Chain Risk Analysis: Offering a comprehensive solution to optimize supply chain risk management and decision-making.

Supply Chain Mapping: Providing a holistic approach to supply chain management, offering a comprehensive view of the entire process.

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GaN Semiconductor Device Market Booming Worldwide with Latest Trend and Future Scope by 2028

The global GaN semiconductor device market size is estimated to be worth USD 21.1 billion in 2023 and is projected to reach USD 28.3 billion by 2028, at a CAGR of 6.1% during the forecast period.

Increasing adoption of GaN semiconductor devices in consumer and business enterprises, surging deploymnet of GaN semiconductor devices in energy & power industry, and growing integration of GaN semiconductor devices in automotive industry are some of the major factors driving the market growth globally.

Discrete semiconductor segment to register largest market share in the GaN semiconductor device market during forecast period

Discrete GaN semiconductor components include GaN transistors and GaN diodes that are individually packaged and marketed. These components are used in diverse applications such as power supply units, inverters, and radio frequency (RF) amplifiers. GaN transistors and diodes effectively manage substantial voltage and current levels, leading to powerful designs. Additionally, they enable more compact and lightweight circuits suitable for applications where constraints on size and weight are paramount.

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Power & Energy to register highest CAGR in the GaN semiconductor device market during forecast period The energy & power segment is expected to grow at the highest CAGR during the forecast period. This growth can be attributed to the rising integration of GaN semiconductor devices into electronic systems to work in elevated temperatures, pressures, and voltages. Moreover, The GaN semiconductor technology foresees extensive adoption in energy and power solutions, encompassing realms such as energy storage systems, solar DC to AC inverters, AC solar panels, and volt-ampere reactive (VAR) compensators in the future.

Asia Pacific held for the largest GaN semiconductor device market share in 2022 Asia Pacific is accounted for the largest share of the GaN semiconductor device market in 2022. The presence of established several semiconductor manufacturing companies such as Toshiba (Japan), Nichia Corporation (Japan), and Mitsubishi Electric (Japan), increasing integration in consumer & business enterprise verticals, government-led initiatives for innovation and industrial development are the major factors driving the market growth in Asia Pacific.

GaN Semiconductor Device Market Key Players The major players in the GaN semiconductor device companies include Qorvo, Inc. (US), Wolfspeed, Inc. (US), Sumitomo Electric Industries, Ltd. (Japan), MACOM Technology Solutions Holdings, Inc. (US) and Infineon Technologies AG (Germany). These companies have used both organic and inorganic growth strategies such as product launches, agreements, collaborations, acquisitions, partnerships and expansions to strengthen their position in the market.

Motion Control Companies - ABB (Switzerland) and FANUC Corporation (Japan) are the Key Players

The motion control market is estimated to be worth USD 16.5 billion in 2024 and is projected to reach USD 21.6 billion by 2029 at a CAGR of 5.5% during the forecast period. The global Motion Control Market is primarily propelled by the increasing demand for automation across industries, aiming for enhanced efficiency and precision in manufacturing processes. Technological advancements in motion control systems, offering improved performance and reliability, contribute significantly to market growth.

Major Motion Control companies include:

ABB (Switzerland),

FANUC Corporation (Japan),

Siemens (Germany),

Yaskawa Electric Corporation (Japan), and

Mitsubishi Electric Corporation (Japan).

Major players in the Motion Control market are strategically implementing initiatives to establish a robust global presence. These efforts often involve a combination of mergers and acquisitions, strategic partnerships, and geographic expansions. Key players are actively seeking to broaden their market reach by acquiring companies with complementary technologies or a strong regional presence. Additionally, partnerships with local distributors and system integrators enable these players to enhance their market penetration and provide customized solutions tailored to specific regional needs.

ABB is a Swiss multinational corporation, a technology leader in terms of electrification, industrial automation, motion, and robotics and discrete automation. ABB offers a range of autonomous mobile robot products that are designed to operate in industrial and logistics settings, improving efficiency and safety. ABB’s products and services are used by a wide range of industries, including utilities, transportation, manufacturing, and infrastructure. The company operates through four business segments, namely, Electrification, Motion, Process Automation, and Robotics & Discrete Automation.

FANUC Corporation is a leading global manufacturer and supplier of factory automation solutions and industrial robots. The company has become a pioneer in the field of computer numerical control (CNC) systems, producing cutting-edge technologies that empower industries with precision, efficiency, and productivity. FANUC CORPORATION's diverse range of products includes industrial robots, CNC systems, machine tools, and factory automation solutions, catering to various sectors such as automotive, electronics, aerospace, and more.  FANUC CORPORATION operates its business through four divisions, namely, Factory Automation (FA), Robot, Robomachine, and Service. FANUC manufactures products such as servo motors, servo amplifiers, lasers, robot machines, field systems, and robots. The company operates its business through four segments—Field Automation (FA), Robot, Robomachine, and Service.

Mitsubishi Electric Corporation manufactures a range of control and power electronics products based on automation technologies. The company is well-known for its air conditioning products, home appliances, automotive equipment, rail transportation systems, satellites, digital signage, semiconductors, and electronics. It provides industrial automation solutions in Asia, with its origin in Japan. The company operates through six business segments, namely, Energy and Electric Systems, Industrial Automation Systems, Home Appliances, Information and Communication Systems, Electronic Devices, and Others (Procurement, Logistic, Real Estate, Advertising, Finance, and Other Services).

Siemens is a global powerhouse in the fields of electrification, automation, and digitalization. The company has evolved into a diversified conglomerate with a significant impact on various industries worldwide. Siemens operates across numerous sectors, including energy, healthcare, industry, and infrastructure, delivering cutting-edge solutions that address complex challenges and drive sustainable progress. It operates through six business segments, namely, Digital Industries, Smart Infrastructure, Mobility, Siemens Healthineers, Siemens Financial Services, and Portfolio Companies.

Yaskawa Electric Corporation is one of the leading manufacturers in the fields of drive technology, industrial automation, and robotics in Japan. The company is operating its business through three segments, namely Motion Control, Robotics, and System Engineering. Yaskawa has been ensuring to provide cutting-edge technologies in its products and services. Yaskawa Electric Corporation is a company involved in the manufacturing, sales, installation, and maintenance of control systems and industrial products.

STMicroelectronics' SiC Technology Enables BorgWarner's Viper Power Module Design to Power Volvo's Next-Gen Electric Vehicles

【Lansheng Technology Information】September 7, 2023, STMicroelectronics will cooperate with BorgWarner Corporation (NYSE: BWA), a global leader in providing innovative and sustainable mobility solutions, for BorgWarner Proprietary Viper-based power modules provide STMicroelectronics' latest third-generation 750V silicon carbide (SiC) power MOSFET chips. BorgWarner will use the power module to design electric drive inverter platforms for Volvo's current and future electric models.

Javier Varela, Chief Operating Officer and Deputy Chief Executive Officer of Volvo, said: "This partnership will increase the range and charging speed of Volvo electric vehicles, and has the opportunity to further increase the popularity of Volvo electric vehicles in the market, while also helping us in 2030. To achieve the goal of electrification of all models, and to improve the vertical integration of the industrial chain, and strengthen the control over key automotive components."

Javier Varela, Chief Operating Officer and Deputy Chief Executive Officer of Volvo, said: "This partnership will increase the range and charging speed of Volvo electric vehicles, and has the opportunity to further increase the popularity of Volvo electric vehicles in the market, while also helping us in 2030. To achieve the goal of electrification of all models, and to improve the vertical integration of the industrial chain, and strengthen the control over key automotive components."

In order to give full play to the advantages of STMicroelectronics' SiC MOSFET chips, BorgWarner and STMicroelectronics' technical team work closely together to strive to perfectly match STMicroelectronics' chips with BorgWarner's Viper power switches to maximize inverter performance. Reduce the size of the electric drive architecture and improve economic efficiency. The cooperation between the two companies can better realize the scale manufacturing effect and meet the rapidly growing demand of the electric vehicle market.

Marco Monti, President of STMicroelectronics Automotive and Discrete Group (ADG), said: "STMicroelectronics' cooperation with BorgWarner, the world's leading automotive electrification supplier, will help Volvo provide customers with outstanding vehicle performance and range. We will continue to expand SiC production capacity and increase SiC supply, including vertically integrated supply chains, to fully support the electrification and energy-efficient transformation of global automotive and industrial customers."

STMicroelectronics STPOWER SiC power chips are mass-produced in two front-end factories in Italy and Singapore, and advanced packaging and testing are carried out in the back-end manufacturing plants in Morocco and China. In October 2022, STMicroelectronics announced that it will expand the production capacity of wide bandgap products and build a new comprehensive SiC substrate manufacturing plant in Catania, Italy. Catania is not only the power semiconductor technology center of STMicroelectronics, but also the research and development and manufacturing base of silicon carbide.

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Global Top 15 Companies Accounted for 58% of total Smart Access Control market (QYResearch, 2021)

According to the new market research report “Global Smart Access Control Market Report 2023-2029”, published by QYResearch, the global Smart Access Control market size is projected to reach USD 1.83 billion by 2029, at a CAGR of 5.1% during the forecast period.

Figure.   Global Smart Access Control Market Size (US$ Million), 2018-2029

Figure.   Global Smart Access Control Top 15 Players Ranking and Market Share (Ranking is based on the revenue of 2022, continually updated)

The global key manufacturers of Smart Access Control include Ring (Amazon), Zkteco Co.,Ltd, Salto Systems, Hivision, ASSA ABLOY, Johnson Controls, dormakaba, GU Group, Suprema, HEJIANGDAHUATECHNOLOGYCO.,LTD. , etc. In 2021, the global top 10 players had a share approximately 58.0% in terms of revenue.

About QYResearch

QYResearch founded in California, USA in 2007.It is a leading global market research and consulting company. With over 16 years’ experience and professional research team in various cities over the world QY Research focuses on management consulting, database and seminar services, IPO consulting, industry chain research and customized research to help our clients in providing non-linear revenue model and make them successful. We are globally recognized for our expansive portfolio of services, good corporate citizenship, and our strong commitment to sustainability. Up to now, we have cooperated with more than 60,000 clients across five continents. Let’s work closely with you and build a bold and better future.

QYResearch is a world-renowned large-scale consulting company. The industry covers various high-tech industry chain market segments, spanning the semiconductor industry chain (semiconductor equipment and parts, semiconductor materials, ICs, Foundry, packaging and testing, discrete devices, sensors, optoelectronic devices), photovoltaic industry chain (equipment, cells, modules, auxiliary material brackets, inverters, power station terminals), new energy automobile industry chain (batteries and materials, auto parts, batteries, motors, electronic control, automotive semiconductors, etc.), communication industry chain (communication system equipment, terminal equipment, electronic components, RF front-end, optical modules, 4G/5G/6G, broadband, IoT, digital economy, AI), advanced materials industry Chain (metal materials, polymer materials, ceramic materials, nano materials, etc.), machinery manufacturing industry chain (CNC machine tools, construction machinery, electrical machinery, 3C automation, industrial robots, lasers, industrial control, drones), food, beverages and pharmaceuticals, medical equipment, agriculture, etc.

Field Programmable Gate Array (FPGA) Market - Forecast(2024 - 2030)

The FPGA market was valued at USD 4.79 Billion in 2017 and is anticipated to grow at a CAGR of 8.5% during 2017 and 2023. The growing demand for advanced driver-assistance systems (ADAS), the growth of IoT and reduction in time-to-market are the key driving factors for the FPGA market. Owing to benefits such as increasing the performance, early time to market, replacing glue logic, reducing number of PCB spins, and reducing number of parts of PCB, field programmable gate arrays (FPGA’s) are being used in many CPU’s. Industrial networking, industrial motor control, industrial control applications, machine vision, video surveillance make use of different families of FPGA’s.

North America is the leading market for field programmable gate arrays with U.S. leading the charge followed by Europe. North America region is forecast to have highest growth in the next few years due to growing adoption of field programmable gate arrays.

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What is Field Programmable Gate Arrays?

Field Programmable Gate Arrays (FPGAs) are semiconductor devices. The lookup table (LUT) is the basic block in every FPGA. Different FPGAs use variable sized LUTs. A lookup table is logically equivalent to a RAM with the inputs being the address select lines and can have multiple outputs in order to get two Boolean functions of the same inputs thus doubling the number of configuration bits. FPGAs can be reprogrammed to desired application or functionality requirements after manufacturing. This differentiates FPGAs from Application Specific Integrated Circuits (ASICs) although they help in ASIC designing itself, which are custom manufactured for specific design tasks. 

In a single integrated circuit (IC) chip of FPGA, millions of logic gates can be incorporated. Hence, a single FPGA can replace thousands of discrete components. FPGAs are an ideal fit for many different markets due to their programmability. Ever-changing technology combined with introduction of new product portfolio is the major drivers for this industry.

What are the major applications for Field Programmable Gate Arrays?

FPGA applications are found in Industrial, Medical, Scientific Instruments, security systems, Video & Image Processing, Wired Communications, Wireless Communications, Aerospace and Defense, Medical Electronics, Audio, Automotive, Broadcast, Consumer Electronics, Distributed Monetary Systems, Data and Computer Centers and many more verticals.

Particularly in the fields of computer hardware emulation, integrating multiple SPLDs, voice recognition, cryptography, filtering and communication encoding,  digital signal processing, bioinformatics, device controllers, software-defined radio, random logic, ASIC prototyping, medical imaging, or any other electronic processing FGPAs are implied because of their capability of being programmable according to requirement. FPGAs have gained popularity over the past decade because they are useful for a wide range of applications.

FPGAs are implied for those applications in particular where the production volume is small. For low-volume applications, the leading companies pay hardware costs per unit. The new performance dynamics and cost have extended the range of viable applications these days.

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Market Research and Market Trends of Field Programmable Gate Array (FPGA) Ecosystem

FPGA As Cloud Server: IoT devices usually have limited processing power, memory size and bandwidth. The developers offer interfaces through compilers, tools, and frameworks. This creates effectiveness for the customer base and creates strong cloud products with increased efficiency which also included new machine learning techniques, Artificial Intelligence and big data analysis all in one platform. Web Service Companies are working to offer FPGAs in Elastic Compute Cloud (EC2) cloud environment. 

Artificial Intelligence: As an order of higher magnitude performance per Watt than commercial FPGAs and (Graphical Processing Unit) GPUs in SOC search giant offers TPUs (Google’s Tensor Processing Units). AI demands for higher performance, less time, larger computation with more power proficient for deep neural networks. Deep neural network power-up the high-end devices. Google revealed that the accelerators (FGPAs) were used for the Alpha GO systems which is a computer developed by Google DeepMind that plays the board game Go.  CEA also offers an ultra-low power programmable accelerator called P-Neuro.

Photonic Networks for Hardware Accelerators: Hardware Accelerators normally need high bandwidth, low latency, and energy efficiency. The high performance computing system has critical performance which is shifted from the microprocessors to the communications infrastructure. Optical interconnects are able to address the bandwidth scalability challenges of future computing systems, by exploiting the parallel nature and capacity of wavelength division multiplexing (WDM). The multi-casted network uniquely exploits the parallelism of WDM to serve as an initial validation for architecture. Two FPGA boarded systems emulate the CPU and hardware accelerator nodes. Here FPGA transceivers implement and follow a phase-encoder header network protocol. The output of each port is individually controlled using a bitwise XNOR of port’s control signal. Optical packets are send through the network and execute switch and multicasting of two receive nodes with most reduced error

Low Power and High Data Rate FPGA: “Microsemi” FPGAs provides a non-volatile FPGA having 12.7 GB/s transceiver and lower poor consumption less than 90mW at 10 GB/s. It manufactured using a 28nm silicon-oxide-nitride-oxide-silicon nonvolatile process on standard CMOS technology. By this they address cyber security threats and deep submicron single event upsets in configuration memory on SRAM-based FPGA. These transceivers use cynical I/O gearing logic for DDR memory and LVDS. Cryptography research provides differential power analysis protection technology, an integrated physical unclonable function and 56 kilobyte of secure embedded non-volatile memory, the built-in tamper detectors parts and counter measures.

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Speeds up FPGA-in-the-loop verification: HDL Verifier is used to speed up FPGA-in-the-loop (FIL) verification. Faster communication between the FPGA board and higher clock frequency is stimulated by the FIL capabilities. This would increase the complexity of signal processing, control system algorithms and vision processing. For validation of the design in the system context simulate hardware implementation on an FPGA board. HDL Verifier automates the setup and connection of MATLAB and Simulink test environments to designs running on FPGA development boards. The R2016b has been released that allows engineers to specify a custom frequency for their FPGA system clock with clock rates up to five times faster than previously possible with FIL. This improves faster run-time. From MATLAB and Simulink is an easy way to validate hardware design within the algorithm development environment

Xilinx Unveils Revolutionary Adaptable Computing Product Category: Xilinx, Inc. which is leader in FGPAs, has recently announced a new product category which is named as Adaptive Compute Acceleration Platform (ACAP) and has the capabilities far beyond of an FPGA. An ACAP is a highly integrated multi-core heterogeneous compute platform that can be changed at the hardware level to adapt to the needs of a wide range of applications and workloads. ACAP has the capability of dynamic adaption during operation which enables it to deliver higher performance per-watt levels that is unmatched by CPUs or GPUs.

Lattice Releases Next-Generation FPGA Software for Development of Broad Market Low Power Embedded Applications: Lattice Semiconductor, launched its FPGA software recently. Lattice Radiant targeted for the development of broad market low power embedded applications. Device’s application expands significantly across various market segments including mobile, consumer, industrial, and automotive due to is rich set of features and ease-of-use, Lattice Radiant software’s support for iCE40 Ultra plus FPGAs. ICE40 Ultra Plus devices are the world’s smallest FPGAs with enhanced memory and DSPs to enable always on, distributed processing. The Lattice Radiant software is available for free download.

Who are the Major Players in market?

The companies referred in the market research report include Intel Inc, Microsemi, Lattice Semiconductor, Xilinx, Atmel, Quick Logic Corp., Red Pitaya, Mercury Computer, Nallatech Inc., Achronix Semiconductor Corporation, Acromag Inc., Actel Corp., Altera Corp.

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What is our report scope?

The report incorporates in-depth assessment of the competitive landscape, product market sizing, product benchmarking, market trends, product developments, financial analysis, strategic analysis and so on to gauge the impact forces and potential opportunities of the market. Apart from this the report also includes a study of major developments in the market such as product launches, agreements, acquisitions, collaborations, mergers and so on to comprehend the prevailing market dynamics at present and its impact during the forecast period 2017-2023.

All our reports are customizable to your company needs to a certain extent, we do provide 20 free consulting hours along with purchase of each report, and this will allow you to request any additional data to customize the report to your needs.

Key Takeaways from this Report

Evaluate market potential through analyzing growth rates (CAGR %), Volume (Units) and Value ($M) data given at country level – for product types, end use applications and by different industry verticals.

Understand the different dynamics influencing the market – key driving factors, challenges and hidden opportunities.

Get in-depth insights on your competitor performance – market shares, strategies, financial benchmarking, product benchmarking, SWOT and more.

Analyze the sales and distribution channels across key geographies to improve top-line revenues.

Understand the industry supply chain with a deep-dive on the value augmentation at each step, in order to optimize value and bring efficiencies in your processes. 

Get a quick outlook on the market entropy – M&A’s, deals, partnerships, product launches of all key players for the past 4 years. 

Evaluate the supply-demand gaps, import-export statistics and regulatory landscape for more than top 20 countries globally for the market. 

North America Industrial Annunciator Market Analysis by Recent Developments and Business Outlook to 2027

The North America Industrial Annunciator Market report is the most important research for who looks for all information about the market. The report covers all information about the regional markets, including historical and future trends for market dominance, size, trades, supply, competitors, and prices, as well as key vendor information across the region. Forecast market information, SWOT analysis, North America Industrial Annunciator market scenario, and feasibility study are important aspects in this report.

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Top Companies in the North America Industrial Annunciator Market include:

· ABB Ltd

· AMETEK Inc

· Eaton Corporation plc

· Ronan Engineering Company

· Automation Displays Inc.

· Dwyer Instruments, Inc

· NOTIFIER

· Schweitzer Engineering Laboratories, Inc.

· Apex Automation Solutions

The major players in the North America Industrial Annunciator industry is covered in this report by report, their market share, product portfolio, company profiles. Key market players are analyzed on the basis of production volume, gross margin, market value, and price structure. The competitive market scenario among North America Industrial Annunciator players will help the industry aspirants in planning their strategies. The statistics presented in this report are an accurate and useful guide to shaping your business growth.

North America Industrial Annunciator Market Split by Product Type and Applications:

This report segments the North America Industrial Annunciator market on the basis of Types is:

· Conventional Annunciators

· Dedicated Annunciators

On the basis of Application, the North America Industrial Annunciator Market is segmented into:

· Process Industry

· Discrete Industry

Objectives of the Report:

· To carefully analyze and forecast the size of the North America Industrial Annunciator market by value and volume.

· To estimate the market shares of major segments of the North America Industrial Annunciator.

· To showcase the development of the North America Industrial Annunciator market in different parts of the world.

· To analyze and study micro-markets in terms of their contributions to the North America Industrial Annunciator market, their prospects, and individual growth trends.

· To offer precise and useful details about factors affecting the growth of the North America Industrial Annunciator

· To provide a meticulous assessment of crucial business strategies used by leading.

Finally, the report presents market information in the most comprehensive manner. The report structure has been maintained to provide maximum business value. It provides critical insight into market dynamics and enables strategic decision-making for established market participants and those willing to enter the market.

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Worldwide Semiconductor Revenue Grew 1.1% in 2022, Gartner says

Worldwide Semiconductor Revenue Grew 1.1% in 2022, Gartner says. Memory Market Was Worst-Performing Segment, Declining 10% With Continued Challenges in 2023. STAMFORD, Conn., January 17, 2023 - Worldwide semiconductor revenue increased 1.1% in 2022 to total $601.7 billion, up from $595 billion in 2021, according to preliminary results by Gartner, Inc. The combined revenue of the top 25 semiconductor vendors increased 2.8% in 2022 and accounted for 77.5% of the market. ���2022 began with many semiconductor devices in shortage resulting in extended lead times and increasing pricing which led to reduced electronic equipment production for many end markets. As a result, OEMs started hedging themselves from shortages by stockpiling chip inventory,” said Andrew Norwood, VP Analyst at Gartner. “However, by the second half of 2022, the global economy began to slow under the strain of high inflation, rising interest rates, higher energy costs and continued COVID-19 lockdowns in China, which impacted many global supply chains. Consumers also began to reduce spending, with PC and smartphone demand suffering, and then enterprises starting to reduce spending in anticipation of a global recession, all of which impacted overall semiconductor growth.” Samsung Electronics maintained the top spot although revenue declined 10.4% in 2022, primarily due to declines in memory and NAND flash sales (see Table 1). Intel held on to the No. 2 position with 9.7% market share. The company was impacted by the significant decline of the consumer PC market and strong competition in its core x86 processor businesses and revenue growth declined 19.5%.

Top 10 Semiconductor Vendors by Revenue, Worldwide, 2022 (Millions of U.S. Dollars)

2022 Rank2021 RankVendor2022 Revenue2022 Market Share (%)2021 Revenue2021-2022 Growth (%)11Samsung Electronics65,58510.973,197-10.422Intel58,3739.772,536-19.533SK Hynix36,2296.037,192-2.645Qualcomm34,7485.827,09328.354Micron Technologies27,5664.628,624-3.766Broadcom23,8114.018,79326.7710AMD23,2853.916,29942.988Texas Instruments18,8123.117,2728.997MediaTek18,2333.017,6173.51011Apple17,5512.914,58020.4  Others (outside top 10)277,50146.1271,7492.1  Total Market601,694100.0594,9521.1Source: Gartner (January 2023)

Memory Revenue Declined 10% in 2022

Memory, which accounted for around 25% of semiconductor sales in 2022, was the worst-performing device category, experiencing a 10% revenue decrease. By the middle of 2022, the memory market was already showing signs of a significant collapse in demand as electronic equipment OEMs started to deplete memory inventory they had been holding in anticipation of stronger demand. Conditions have now worsened to the point where most memory companies have announced capital expenditure (capex) reductions for 2023, and some have cut wafer production to reduce inventory levels and try to bring the markets back into balance.

Nonmemory Revenue Up 5% in 2022

Overall nonmemory revenue grew 5.3% in 2022, but the performance varied wildly across the different device categories. The strongest growth came from analog with a 19% increase, closely followed by discretes, up 15% from 2021. The growth for both analog and discretes was driven by strong demand from the automotive and industrial end markets underpinned by secular growth trends in vehicle electrification, industrial automation, and energy transition. Read the full article

The Global Machine Vision Market to Develop at 7.75% CAGR by 2028

Triton Market Research presents the Global Machine Vision Market report segmented by Verticals (Automotive, Electronics & Semiconductors, Healthcare, Food & Packaging, Other Verticals), by Application (Inspection, Gauging, Guidance, Identification, Other Applications), by Components (Hardware [ASMV, Cameras, Sensors, Illuminations, Processors, Other Hardware Components], Software), by Type (1D Machine Vision, 2D Machine Vision, 3D Machine Vision), by Geographical Region (North America, Europe, Asia-Pacific, Latin America, Middle East and Africa), discussing Market Summary, Industry Outlook, Drivers, Challenges, Opportunities, Competitive Landscape, Research Methodology & Scope, and Global Market Size, Forecasts, & Analysis (2022-2028).

Triton Market Research has put forth that the Global Machine Vision Market would evolve at a CAGR of 7.55% over the estimated period 2022 to 2028.

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 An increase in the number of smart factories has been observed in recent years. A smart factory enables the complete automation of facilities, which reduces the human involvement, machine defects & downtime, and operational costs. At the same time, it improves information sharing and operational control, thereby avoiding major factory accidents. The increase in smart factories is thereby driving the market growth.

On the other hand, despite the multiple business benefits it offers, machine vision is yet to be utilized to its full potential. This is because MV systems require a high level of expertise for their successful post-implementation. It is majorly restricting the growth of the market studied.

The Asia-Pacific region holds the major chunk of the global machine vision market, and is anticipated to continue its lead until the end of the forecasted period. The APAC is fast becoming the new hub of the manufacturing industry. And, owing to the presence of a high number of discrete manufacturing factories, the machine vision market is anticipated to significantly in the region. Several industrial set-ups are adopting machine vision systems in their facilities to improve their manufacturing efficiency and deal with the rising wages & pressure to enhance the working condition of workers.

Basler AG, Cognex Corporation, National Instruments Corporation, Perceptron Inc, Flir Systems Inc, Allied Vision Technologies GmbH, Teledyne Technologies Incorporated, Isra Vision AG, Omron Corporation, Baumer Electric AG, Optotune AG, Keyence Corporation, Datalogic SpA, USS Vision, and Jai AS are some of the dominant players in this market.

The global market for machine vision is highly competitive, with several local, regional, and international players, ranging from large to small. They are trying to compete by offering the same characteristics and similar prices or by offering similar product features at lower prices and also by acquiring major companies.

The numerous factors responsible for the competitive rivalry among the existing players within any industry include high concentration level, exit barriers, industry demand & growth, high strategic stakes, and product & service differentiation. Additionally, different companies in the market operate with varied technologies for varied applications. Besides, machine vision systems are not standardized but application-specific. This has largely increased the level of competition among players.

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Is the LED plant light for hemp the right choice?

LED plant growth lights are now powerful enough and have sufficient spectrum, and are considered to be the ideal choice for cannabis plant growth lights. Using the correct umols and PAR values, LED grow lights will provide larger and thicker results than HID or high pressure sodium lights.

HPS lamps (high pressure sodium lamps) have been a confident leader in the cannabis lighting system market for decades, and although other technologies exist, they are unlikely to change their status. We will carefully study the differences between different types of lamps and try to give opinions on their expectations.

So what is HPS, LED (light emitting diode)?

The HPS lamp emits light by passing high-pressure pulse energy through a sealed quartz tube filled with sodium vapor and some other elements, xenon and mercury. As it heats up, the gas starts to glow. Sodium emits a strong orange, yellowish light. Xenon and mercury can be used to change the spectrum. Xenon and mercury emit in the blue range of the visible spectrum, making the light whiter.

Light emitting diode (LED) lamps are semiconductors that allow current to pass almost unimpeded in one direction but provide very strong resistance in the other direction (through a "pn junction"). On one side of the junction, the material is processed in a way that receives additional electrons, and on the other side, the material that does not have enough electrons is processed. By applying a voltage, we force electrons to move through the junction to fill the "gap" on the other side. This leads to luminescence, the color of which depends on the material used. Phosphides and nitrides of gallium, aluminum, zinc and silicon are most commonly used here.

Photoelectric efficiency The efficiency of a lamp can be expressed by a simple formula: the total amount of light energy (lumens) of the lamp divided by its total energy consumption (watts). The minimum power of DNAT is 90 lm/W, although for some brands, this figure reaches 150 lm/W, or even higher. More and more grow lights are also evaluated in PAR (Photosynthetically Active Radiation), which is measured in µmol/s (the number of photons per second per 1m2 of the surface of the plant block).

µmol/s is an increasingly popular metric for growing lights because it measures the amount of light reaching the plant, rather than what the human eye sees.

The most efficient HPS lamp to date produces approximately 150 lumens per square meter. For example, the GE Lucalox 600W lamp produces 90,000 initial lumens ("initial lumens" means the radiation intensity of the first 100 hours), while the best 600W Lumatek lamps produce 92,000. Although not done before, for the new model, HPS starts to display and PAR indicator. For example, the output of Lumatek 600W is 1030 µmol/s.

For LED plant lights, lm/W is considered to have less "right to speak" than PAR. This is because the lm/W of red and blue lamps is usually much lower because they produce the most important frequency of photosynthesis, and the production of "inefficient" light is minimized.

However, newer LED plant lights use multiple frequencies to create a richer, more efficient, and fuller spectrum, which is believed to be beneficial for plant growth, and usually includes discrete white LEDs as well as red and purple. These newer panels sometimes express efficiency in lm/W. Well-known manufacturers should at least indicate PAR. For example, the British company Budmaster's 410W full-spectrum panel (Budmaster II 675 GOD) indicates the PAR value at different distances from the lamp (the longer the distance, the lower the PAR, because fewer photons will hit the surface of the plant). At 31cm, the PAR of the lamp just exceeds 2000 µmol/s.

spectrum Although progress has not avoided the development of HPS technology, it is believed that these lamps only present a weak natural sunlight appearance compared to more modern lighting systems. If xenon and mercury are not added, sodium itself will emit red and yellow light. However, there have been new "full spectrum" lights that actually have two arcs, that is, they are a mixture of DNAT and DRI. So, for example, Hortilux Super Blue HPS/MH combines 600W HPS and 400W DRI to provide an initial lumens of 110,000 and simulate a spectrum that is as close to natural as possible.

At the moment, LED plant lights may be the best in terms of frequency spectrum, because the most advanced models provide up to 11 frequencies, which is essential for factory development. For example, Fanke Technology GLMX720 720W LED plant light, equivalent to 1000W HPS, and provides 11 frequencies-from ultraviolet to infrared.

Why LED plant lights are the obvious choice when growing hemp, industrial hemp, etc.

Light is essential for the growth of plants. For photosynthesis in plants, light must exist. Advances in technology provide an alternative to sunlight to help crop growth. If you plan to grow indoor plants, or if you live in an area with insufficient sunlight, you can use a grow light.

Purchasing LED plant lights

LED grow lights have been proven to be the best choice for indoor plant growth. Since they are the first choice of many growers, there are many options on the market. Pay attention when buying LED grow lights.

When setting up an indoor garden, you need to make sure your plants are healthy and productive. One way to ensure that this happens is to buy the right LED grow lights. This can be a daunting task, especially if you have never bought an LED grow light in the past.

Be careful when buying grow lights. Buying LED plant growth lights will be a high initial investment. Although the initial cost may be high, they will provide you with efficiency and longevity, which can offset the high cost in the long run.

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Semiconductor Market: High Consumption of Electronic devices to fuel Demand for Semiconductors

The global  semiconductor market  is projected to reach USD 730.29 billion by 2026, exhibiting a CAGR of 5.2% during the forecast period. The increasing utilization and consumption of consumer electronic devices will fuel demand for semiconductors during the forecast period. Furthermore, the rising demand for advanced semiconductor chips in the industrial application will contribute positively to the semiconductor market growth in the forthcoming years. In addition, the penetration of smartphones will fuel demand for semiconductors, which in turn will boost the semiconductor market revenue.

According to the report, published by Fortune Business Insights, titled “Semiconductor Market Size, Share & Industry Analysis, By Components (Memory Devices, Logic Devices, Analog IC, MPU, Discrete Power Devices, MCU, Sensors and Others), By Application (Networking & Communications, Data Processing, Industrial, Consumer Electronics, Automotive, Government and Others) and Regional Forecast, 2019-2026” the market size stood at USD 488.07 billion in 2018. The report is aimed at delivering a comprehensive view of the semiconductor market dynamics and structure by identifying and providing information regarding the key market segments. It also focuses on an all-encompassing analysis of leading market players by financial position, product, product portfolio, price, growth strategies, and regional presence. It offers PORTER’s analysis and SWOT analysis to record the question of shareholders and highlights the investment potential in the upcoming future. It also showcases different procedures and strategies of companies currently operating in the semiconductor market. It further examines the components, convincing market expansion, growth patterns, restricting factors, and market strategies.

 To Gain More Insights into the Semiconductor Market, Browse Summary of the Research Report – https://www.fortunebusinessinsights.com/semiconductor-market-102365

 Rising Application of Semiconductors in Automotive to Stimulate Market

The automotive segment is expected to hold the lion’s share during the forecast period. The growth of the segment is attributed to the penetration of electric and hybrid cars. The rising demand for semiconductors for the production of conventional cars will also boost the semiconductor market share in the forthcoming years. Furthermore, the industrial application segment is likely to account for maximum share in the market owing to the increasing implementation of Industry 4.0, IoT, artificial intelligence and big data. The implementation of these technologies will improve the manufacturing process and therefore create lucrative business opportunities for the market in the foreseeable future. Moreover, the surge in the use of smartphones and the introduction of 5G technology will have a positive impact on the semiconductor market trends during the forecast period.

 Some of the Major Companies Operating in the Semiconductor Market Include:

·         Broadcom, Inc.

·         Intel Corporation

·         Qualcomm

·         Samsung Electronics

·         SK Hynix

·         Taiwan Semiconductors

·         Texas Instruments

·         Toshiba Corporation

·         Maxim Integrated Products, Inc.

·         Micron Technology

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 Growing Adoption of Electronics to Enable Speedy Growth in Aisa Pacific

Asia Pacific generated a revenue of USD 264.14 billion in 2018 and is expected to grow rapidly during the forecast period owing to the growing consumption and adoption of electronic devices. Moreover, the increasing use of IoT and LTE is expected to create new opportunities for the market in Asia Pacific in the forthcoming years. North America is predicted to witness high demand for semiconductors during the forecast period. The growth in the region is attributed to increasing R&D investments in the semiconductor. According to the Semiconductor Industry Association, the U.S. semiconductor industry expenditures in R&D increased at a compound annual growth rate of about 7.3 percent from 1998 to 2018. Moreover, Europe is predicted to grow substantially during the forecast period owing to the increasing application of semiconductors in telecom & network, as well as the automotive industry. The growing investment by key players in the innovation and advancement of semiconductors to cater to the increasing demand from various industries will aid the expansion of the semiconductor market in Europe.  In addition, the rising utilization of electronic goods across various countries such as the UK, France, and Germany will also support the growth of the market in Europe.

Major Table of Content for Semiconductor Market:

 Definition,      By Segment

 Research      Approach

 Sources

 Drivers,      Restraints and Opportunities

 Emerging      Trends

 Macro      and Micro Economic Indicators

 Consolidated      SWOT Analysis of Key Players

 Porter’s      Five Forces Analysis

  Memory       Devices

  Logic       Devices

  Analog       IC

  MPU

  Discrete       Power Devices

  MCU

  Sensors

  Others       (DSP, etc.)

    Networking       & Communications

  Data       Processing

  Industrial

  Consumer       Electronics

  Automotive

  Government

    North       America

  Europe

  Asia       Pacific

  Middle       East & Africa

  Latin       America

 TOC Continued…!

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Automotive MCU is still booming

【Lansheng Technology Information】At present, in the field of automotive MCU, Renesas Electronics, NXP and Infineon are in the leading position. Renesas Electronics has formed close cooperation with well-known Japanese car companies in the development process, and improved the automotive industry through stable supply and generation selection. The competitiveness of electronic MCU products; NXP strengthened the automotive field after acquiring Freescale in 2015, and the strength of automotive MCU has been greatly improved; Infineon is deeply involved in automotive electronics, industrial control, communications, medical and other fields. , perfected the automotive electronics MCU product line.

Regarding the automotive MCU market, Infineon’s 2023Q3 automotive business reached a record high of 2.129 billion euros, mainly due to the growth of microcontrollers. In addition, in terms of orders in hand, as of the end of June, the company's total order backlog was 32 billion euros, more than half of which were automotive orders; Renesas Electronics' automotive business in 2023Q2 increased by 0.7% month-on-month and 3.4% year-on-year, accounting for 46%, reaching 1694 billion yen, ranking second in historical quarterly revenue; NXP's automotive business revenue in 2023Q2 was US$1.87 billion, a year-on-year increase of 9% and a month-on-month increase of 2%, close to the high end of the company's guidance.

The demand for the Q3 automotive business will continue to remain strong, and a few supply shortages will continue until the end of the year; STMicroelectronics achieved revenue growth in both sub-product divisions of the 2023Q2 Automotive Products and Discrete Device Products Division (ADG), of which operating profit increased by 73.8%. $624 million. Operating margin was 31.9%, up 7.2% year-over-year.

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