全球的Energy Harvesting（環境發電）市場：市佔率・策略・預測・奈米科技的影響（2012-2018年）

全球的Energy Harvesting（環境發電）市場：市佔率・策略・預測・奈米科技的影響（2012-2018年） 是由出版商WinterGreen Research, Inc.在2011年11月所出版的。 這份英文市場調查報告書包含625 Pages 價格從美金3600起跳。

簡介

推算2011年將創下5億1,100萬美元市場規模紀錄的全球Energy Harvesting（環境發電）市場，預期2018年將成長為約10倍的51億美元的市場規模。此成長可能是由於裝置價格的下降與高效率化所造成。

本報告，調查分析全球Energy Harvesting（環境發電）市場的現狀與展望，彙整環境發電系統的概要・構成要素・優點/缺點、主要產品的概要、主要技術・週邊技術的概要、產品種類別的出貨預測（∼2018年）、主要企業的檔案資料等，由下列摘要形式闡述。

報告摘要

第1章 環境發電市場：市場概要・市場動態

• 變化的全球經濟
• 無線感測器節點
• 環境發電的價值
• 環境發電系統的構成要素
• 更智慧的運算
• 環境發電的目標市場
• 智慧建築/環境發電
• 運輸產業目標市場
• 為電網安定化的能源儲存
• 應用與印刷電路板電池電源
• 電池的安全性/潛在危險
• 薄膜固體電池
• 做為電化學的電池
• 電池依賴化學能源

第2章 環境發電（振動・熱・壓電）市場的比率・預測

• 環境發電市場
• 環境發電市場的比率
• 環境發電市場預測
• 環境發電的價格
• 薄膜・印刷電池市場的比率
• 薄膜・印刷電池市場的預測
• 更智慧的運算依賴量測裝置
• 奈米科技與次世代系統
• 環境發電：地區分析

第3章 環境發電的產品概要

• 環境發電裝置
• Marlow Industries Inc
• Micropelt的環境發電
• EnOcean
• Arveni
• Boeing
• Ferro Solutions
• KCF Technologies
• Trophos Energy
• Millennial Net的無線感測器網路
• BYD所開發的Fe電池
• MIT研究者
• 線性科技
• ReVolt Technologies，等

第4章 環境發電技術

• 室內使用・產業用途的無線感測器解決方案：綠色且智慧的無線
• 奈米科技與石墨烯
• 環境發電系統的構成要素
• 壓電器裝置
• 能源密度
• SiC基板市場
• Fraunhofer Institute
• Tadiran Batteries
• Perpetua
• ZigBee®聯盟
• ALD 環境發電模組
• Advanced Cerametrics，等

第5章 企業檔案資料

圖表

目錄

LEXINGTON, Massachusetts (November 22, 2011) - WinterGreen Research announces that it has a new study on Energy Harvesting Market Shares and Forecasts, Worldwide, Nanotechnology 2012-2018. Products power sensors that are the base for smarter computing. The 2011 study has 625 pages, 209 tables and figures. Energy harvesting devices are evolving in the context of the development of solid state technology that provides vast improvements. Improvements in energy density are one of the benefits of energy harvesting give to traditional rechargeable and solid state batteries.

Advanced technologies associated are emerging that make energy harvesting feasible. Advanced storage devices are emerging simultaneously. Storage devices can leverage the power captured by energy harvesting devices. Energy storage technologies of super-capacitors and thin-film batteries have become cost-effective. Energy harvesting devices have attained workable levels of efficiency. There are significant cost reductions. Many applications are related to smarter computing that depends on sensors capturing change in conditions and making adjustments to the environment based on measured change.

Existing energy harvesting and storage applications include vibration-based wireless train measuring systems, wireless sensors distributed city wide to implement smart cities, oil field monitoring systems, windup laptops for use in remote regions, and wireless light switches for use in smart buildings. Wireless sensors are self-powering. They can be used to alert and monitor a range of environments and incidents, pollution and forest fires, robberies in a city, temperature in a building, and movement around a border fence.

Energy harvesting technologies include electrodynamics, photovoltaics, piezoelectrics, and thermovoltaics. Photovoltaic systems for solar energy is mostly outside the scope of this study. The energy harvesting and energy storage market factors light harvesting for small devices

Technological developments in the fields of low-power electronics and energy storage systems have allowed energy harvesting to become an increasingly viable technology. It is alternatively referred to as energy scavenging and power harvesting. Energy harvesting technology has become sophisticated and efficient.

Energy harvesting is the use of ambient energy to provide electricity for small electronics, for sensor networks, and for mobile equipment. It is able to provide maintenance free, long life energy for equipment, reducing the need for batteries. Units are used to recharge solid state batteries that can handle as many as 40,000 recharges. Energy harvesting provides the ability to connect with existing devices. Energy harvesting is used when wires or batteries are too expensive to be practical.

‘Energy harvesting’ depends on the capture of ambient energy, its conversion to usable form, and storage. Common examples of energy harvesting include wristwatches powered by body movement and bicycle dynamo powered by the motion of the wheel.

Integrated circuits can perform algorithmic control and achieve wireless communications using tiny amounts of energy. These integrated circuits provide a technological tipping point that permits the evolution of energy-harvesting-based systems from niche products, to widespread use in wireless networks.

According to Susan Eustis, the senior analyst for the study, “The wireless sensor node is the most important product type forecast for growth as an energy-harvesting solution. Wireless sensors are ubiquitous and very attractive products to implement smarter planet initiatives using harvested energy.”

Wireless sensors nodes are commonly placed in hard-to-reach locations. Changing batteries can be costly and inconvenient. Wireless sensors using harvested energy provide off-the-shelf availability of ultra-low-power, single-chip wireless microcontrollers (MCUs) capable of running control algorithms and transmitting data using sophisticated power management techniques.

Energy harvesting markets at $511 million a year market worldwide in 2011 is anticipated to increase tenfold to $5.1 billion by 2018. This strong growth is anticipated to come as units are less expensive and more effective in the same amount of space. Wireless sensor networks are useful almost everywhere, creating the opportunity to implement controls and mange every aspect of human activity in ways that have not even been imagined hitherto.

WinterGreen Research is an independent research organization funded by the sale of market research studies all over the world and by the implementation of ROI models that are used to calculate the total cost of ownership of equipment, services, and software. The company has 35 distributors worldwide, including Global Information Info Shop, Market Research.com, Research and Markets, Bloomberg, and Thompson Financial.

WinterGreen Research authors use a structured, consistent, and detailed research approach. The methodology supports an analytical approach to market research. In depth comparisons are made of many aspects of the market. Data relating to Industry segments is developed to permit presentation of forecasts and market share positioned to have substantive value.

Research has been automated using automation of interactive surveys that implement delta trend analysis and instant messaging in combination with e-mail. Automation is made possible because of a proprietary engine that implements multi-layered cell based analysis. Modular systems support dynamic computing that use a graphical configuration engine to reach more people in a research modality.

Full spectrum research and information services, including market reports, customized research, and customer interviewing are available, reports and research are positioned to provide strategic value to industry participants, strategic planners, and product managers.

New systems combine sales tools and independent industry analysis, seeking to leverage the expertise of the sales force and combine it with the skepticism of the analysts to provide accurate return on investment analysis.

ENERGY HARVESTING EXECUTIVE SUMMARY

• Energy Harvesting Market
• Wireless Sensor Nodes
• Energy Harvesting Minimization of Power Consumption
• Energy Harvesting Market Shares
• Energy Harvesting Market Forecasts

WinterGreen Research Opinion

Energy Harvesting Market Analysis

• Energy Harvester Benefits
• Energy Harvesting Challenges
• Energy Harvesting Current Limitations and Future Issues
• Energy Harvesting Standards

IBM Smarter Planet Description

• Advantages
• Innovations
• Challenges

Marlow Industries Energy Harvesting Description

• Advantages
• Innovations
• Challenges

EnOcean GmbH Energy Harvesting Description

• Advantages
• Innovations
• Challenges

Northrop Grumman Energy Harvesting Description

• Advantages
• Innovations
• Challenges

Perpetua Description

• Advantages
• Innovations
• Challenges

GE Energy Harvesting Description

• Advantages
• Innovations
• Challenges

Alphabet Energy Harvesting Description

• Advantages
• Innovations
• Challenges

Micropelt GmbH Description

• Advantages
• Innovations
• Challenges

Omron Energy Harvesting Description

Reference Market Research Study

1. ENERGY HARVESTING MARKET DESCRIPTION AND MARKET DYNAMICS

• 1.1. World Economy Undergoing A Transformation
  • 1.1.1. Energy Harvesting Process Of Converting Energy From External Sources
  • 1.1.2. Energy Is Everywhere In The Environment
  • 1.1.3. Energy Harvesting
  • 1.1.4. Wireless Sensor Nodes Powered By Batteries
• 1.2. Zero Power Wireless Sensors
  • 1.2.1. Energy Processors and Solid State Batteries Enable Zero Power Wireless Sensors
• 1.3. Energy Harvesting Value
  • 1.3.1. Energy Harvesting Applications
  • 1.3.2. Common Sources of Energy for Harvesting
• 1.4. Components of an Energy Harvesting System
• 1.5. Smarter Computing
  • 1.5.1. Energy Harvesting Power Management Solutions
• 1.6. Energy Harvesting Target Markets
• 1.7. Smart Buildings / Energy Harvesting
  • 1.7.1. Permanent Power for Wireless Sensors
  • 1.7.2. Electric Grid Energy Harvesting Services For Smart Buildings
  • 1.7.3. Commercial Applications For Advanced Batteries
  • 1.7.4. Challenges in Energy Harvesting System Design
  • 1.7.5. Ultra Capacitors
  • 1.7.6. Fuel Cells
• 1.8. Transportation Industry Target Market
  • 1.8.1. Transportation Use of Energy Harvesting
• 1.9. Energy Storage For Grid Stabilization
  • 1.9.1. Local Energy Storage Benefit For Utilities
• 1.10. Applications Require On-Printed Circuit Board Battery Power
  • 1.10.1. Thin-film vs. Printed Batteries
• 1.11. Battery Safety / Potential Hazards
• 1.12. Thin Film Solid-State Battery Construction
• 1.13. Battery Is Electrochemical Device
• 1.14. Battery Depends On Chemical Energy

2. ENERGY HARVESTING: VIBRATION, THERMOVOLTAICS, PIEZOELECTRICS MARKET SHARES AND FORECASTS

• 2.1. Energy Harvesting Market
  • 2.1.1. Wireless Sensor Nodes
  • 2.1.2. Energy Harvesting Minimization of Power Consumption
• 2.2. Energy Harvesting Market Shares
  • 2.2.1. Northrop Grumman
  • 2.2.2. EnOcean Equipped Devices
  • 2.2.3. EnOcean-Enabled Wireless Networks
  • 2.2.4. EnOcean-Enabled Wireless Networks Installed In Over 200,000 Buildings
  • 2.2.5. EnOcean Alliance
  • 2.2.6. Arveni
  • 2.2.7. GE HabiTEQ Systems / EnOcean Energy-Harvesting Joint Venture
  • 2.2.8. Silicon Laboratories
  • 2.2.9. Perpetua
  • 2.2.10. Perpetuum
  • 2.2.11. MicroGen Systems
  • 2.2.12. KCF Technologies
  • 2.2.13. Alphabet Silicon-Based Technology
  • 2.2.14. Arveni's Microgenerator Transforms Mechanical Energy
  • 2.2.15. Arveni Has Technology Specific To Piezo Energy Harvesting
  • 2.2.16. Boeing
  • 2.2.17. Marlow Industries
  • 2.2.18. Marlow Industries Inc
  • 2.2.19. Cymbet
  • 2.2.20. Infinite Power Solutions -
  • 2.2.21. Micropelt Energy Harvesting:
  • 2.2.22. Dust Networks
  • 2.2.23. Ferro Solutions
  • 2.2.24. IBM Positions To Support Sensor Networks
  • 2.2.25. GE Energy
  • 2.2.26. Tadiran Batteries
  • 2.2.27. GMZ
  • 2.2.28. Cymtox
  • 2.2.29. Ferro Solutions
  • 2.2.30. Polatis Photonics
  • 2.2.31. Rockwell Scientific
  • 2.2.32. Omron Micro Electro Mechanical Systems (MEMS) Based Sensors
  • 2.2.33. Omron Photovoltaic Inverter Technology
  • 2.2.34. Selex Galileo
  • 2.2.35. II-VI Incorporated
  • 2.2.36. Leading Energy Harvesting Market Participants by Technology
• 2.3. Energy Harvesting Market Forecasts
  • 2.3.1. Smart City Energy Harvesting Shipments Market Forecasts
  • 2.3.2. Transportation Rail and Electric Vehicle Energy Harvesting Market Forecasts
  • 2.3.3. Smart Building Energy Harvesting Shipments Market Forecasts
  • 2.3.4. Smart Grid Meter and Substation Energy Harvesting Market Forecasts
  • 2.3.5. Sensor Nodes
  • 2.3.6. Military Use of Energy Sensing
  • 2.3.7. Global Desalination Industry
  • 2.3.8. Energy Harvesting Market Industry Segments, Units
• 2.4. Energy Harvesting Pricing
  • 2.4.1. Silicon Labs Energy Harvesting Pricing
  • 2.4.2. EnOcean products
  • 2.4.3. Selected Energy Harvesting Unit Retail Prices
  • 2.4.4. Thin Film Battery: STM, IPS, Cymbet, GS
  • 2.4.5. Thermal EH solutions
• 2.5. Thin Film and Printed Battery Market Shares, Dollars
• 2.6. Thin Film And Printed Battery Market Forecasts
• 2.7. Smarter Computing Depends on Instrumented Devices
  • 2.7.1. IBM The Leader In Smart Computing By A Wide Margin
  • 2.7.2. Advantages Offered By SOA
  • 2.7.3. SOA As An Architecture
  • 2.7.4. Thin Film Battery Market Driving Forces
  • 2.7.5. Smarter Computing Market Driving Forces
  • 2.7.6. IBM WebSphere Product Set Leverages Thin Film Batteries
  • 2.7.7. Thin Film Batteries Market Shares
• 2.8. Nanotechnology Providing Next Generation Systems
  • 2.8.1. Nanotechnology Thin Film Batteries
  • 2.8.2. Silver Nanoplates Silicon Strategy Shows Promise For Batteries
  • 2.8.3. Argonne Scientists Watch Nanoparticles
  • 2.8.4. Thin Film Batteries Use Nanotechnology to Achieve Combining Better Performance With Lower Cost
• 2.9. Energy Harvesting Geographical Region Analysis
  • 2.9.1. Geographical Region Analysis

3. ENERGY HARVESTING PRODUCT DESCRIPTION

• 3.1. Energy Harvesting Devices
• 3.2. Marlow Industries Inc
  • 3.2.1. Marlow Industries Converting Small Degrees Of Temperature Difference Into Milliwatts Of Electrical Power
• 3.3. Micropelt Energy Harvesting:
  • 3.3.1. Micropelt Two Micro Thermogenerators In Series
  • 3.3.2. Micropelt Thermoharvester
• 3.4. EnOcean
  • 3.4.1. EnOcean ECT 310 - Thermo Energy Harvesting
  • 3.4.2. EnOcean Energy Harvesting Wireless Sensor Solutions
  • 3.4.3. EnOcean Alliance Energy Harvesting Solutions
  • 3.4.4. EnOcean-Enabled Wireless Networks
  • 3.4.5. EnOcean Alliance
• 3.5. Arveni
  • 3.5.1. Arveni's Microgenerator Transforms Mechanical Energy
• 3.6. Boeing
• 3.7. Ferro Solutions
  • 3.7.1. Ferro Solutions Energy Harvesters
  • 3.7.2. Ferro Solutions Inductive and PME.
  • 3.7.3. Ferro Solutions Piezo-based PME Energy Harvesters
  • 3.7.4. Ferro Solutions
• 3.8. KCF Technologies
  • 3.8.1. KCF Technologies Energy Harvesting for WMD Detection Systems
  • 3.8.2. KCF Technologies Wireless Accelerometer with Ultra-Compact Energy Harvesting for Rotorcraft
  • 3.8.3. KCF Technologies Harvester-Powered Wireless Accelerometers for Extreme Temperature Monitoring in Fossil Fuel Power Plants
  • 3.8.4. KCF Technologies Wireless Vibration Sensors for Shipboard Environments with Broadband Energy Harvesting
  • 3.8.5. KCF Technologies Harvester-Powered Wireless Sensors for Industrial Machine Monitoring and Condition Based Maintenance
  • 3.8.6. KCF Technologies Piezoelectric and Smart Material Devices
  • 3.8.7. KCF Technologies Compact Narrowband High-Acoustic Sound Source for Particle Agglomeration
  • 3.8.8. KCF Technologies Low-Cost Liquid Atomization and Dispensing with a Miniature Piezoelectric Device
  • 3.8.9. KCF Technologies Extreme Amplitude Piezoelectric Noise Source for HUMVEE Air Filter Cleaning
  • 3.8.10. KCF Technologies High-Temperature Piezoelectric Alarm for Personnel Safety Devices
  • 3.8.11. KCF Technologies Micro-Robot Swarms for Desktop Manufacturing
• 3.9. Trophos Energy
• 3.10. Millennial Net Wireless Sensor Network:
• 3.11. BYD-Developed Fe Battery
• 3.12. Researchers at MIT
• 3.13. Linear Technology
  • 3.13.1. Linear Technology Corporation
• 3.14. ReVolt Technologies
  • 3.14.1. ReVolt Technologies Button Cell Air Electrode
  • 3.14.2. ReVolt Technology Partners With BASF
• 3.15. Cymbet Energizing Innovation
  • 3.15.1. Cymbet Products
  • 3.15.2. Cymbet Rechargeable EnerChips and Effective Capacity
  • 3.15.3. Cymbet Development Support
  • 3.15.4. Cymbet Solid State Energy Storage for Embedded Energy, Power Back-up and Energy Harvesting
  • 3.15.5. Cymbet Energy Harvesting
  • 3.15.6. Cymbet Zero Power Devices
  • 3.15.7. ComtexCymbet EnerChip™ Thin-Film Batteries
  • 3.15.8. Cymbet's EnerChip and Energy Harvesting Solutions
  • 3.15.9. Cymbet EnerChip Solid State Battery Energy Harvesting (EH) / TI's LaunchPad Development Kit
  • 3.15.10. Cymbet Corporation
  • 3.15.11. Cymbet's EnerChip™ EP CBC915,
• 3.16. Infinite Power Solutions (IPS)
  • 3.16.1. Infinite Power Solutions High-Volume Production Line for TFBs
  • 3.16.2. Infinite Power Solutions Solid-State, Rechargeable Thin-Film Micro-Energy Storage Devices
  • 3.16.3. Infinite Power Solutions IPS THINERGY® MEC Products
  • 3.16.4. Infinite Power Solutions THINERGY MEC
  • 3.16.5. Infinite Power Solutions, Inc. Recharge From A Regulated 4.10 V Source
  • 3.16.6. Infinite Power Solutions, Inc. SRAM Backup Guidelines
  • 3.16.7. Infinite Power Solutions, Inc. SRAM Backup Power Solution
  • 3.16.8. Infinite Power Solutions Recharging THINERGY Micro-Energy Cells
  • 3.16.9. Infinite Power Solutions Charging Methods
  • 3.16.10. Infinite Power Solutions, Inc. THINERGY MECs
  • 3.16.11. MicroGen Systems and Infinite Power Solutions Wireless Sensor Network (WSN)
  • 3.16.12. Maxim Integrated, Infinite Power Solutions IC to Integrate All Of The Power-Management Functions For Ambient Energy Harvesting
  • 3.16.13. Maxim Integrated Products (Nasdaq:MXIM) MAX17710 IC Integrates Power-Management
  • 3.16.14. Maxim / Infinite Power Solutions, Inc. (IPS) THINERGY® Solid-State, Rechargeable MEC Battery Products
  • 3.16.15. Maxim introduces MAX17710 PMIC :: Uniquely enables Energy Harvesting with THINERGY MECs
  • 3.16.16. IPS iTHINERGY ADP
  • 3.16.17. IPS and ITT
  • 3.16.18. Infinite Power Solutions, Inc. (IPS) - Global Leader In Manufacturing Solid-State
  • 3.16.19. Infinite Power Solutions (IPS)
• 3.17. Schneider Electric Lighting Control Solutions for Comprehensive Facility Energy Management
• 3.18. Planar
  • 3.18.1. Planar Energy Devices -
  • 3.18.2. Planar Energy's Solid State Batteries New Deposition Process
  • 3.18.3. Planar Energy Print Guide to Recent Battery Advances
  • 3.18.4. Planar Lithium Manganese Dioxide Nanotechnology
  • 3.18.5. Planar Energy Devices PowerPlane MXE Module
• 3.19. IBM Energy Scavenging, Power Scavenging -
• 3.20. Cubic Global Tracking Solutions
• 3.21. Perpetuum
  • 3.21.1. Perpetuum PMG Rail: Transportation / Powering Wireless Rail Monitoring Solutions
  • 3.21.2. Perpetuum Engineering Evaluation and Development
  • 3.21.3. Perpetuum Condition Monitoring
  • 3.21.4. Perpetuum Condition Monitoring Technology To Predict Failure
  • 3.21.5. Perpetuum Holistic View Of Equipment Condition
  • 3.21.6. Perpetuum Need For Greater Accuracy In Condition Assessment Failure Prediction
  • 3.21.7. Perpetuum PMG FSH Free Standing Harvester Integrated Perpetual Power Solutions:
  • 3.21.8. Perpetuum Powering Wireless Rail Monitoring Solutions
  • 3.21.9. Perpetuum Machine Vibration/Motion Energy Harvesting
  • 3.21.10. Perpetuum Vibration Energy Harvesting
  • 3.21.11. Perpetuum Vibration Source
  • 3.21.12. Perpetuum Resonant Frequency: Tuning the Vibration Energy Harvester
  • 3.21.13. Perpetuum Vibration Level: Achieving Maximum Power Output
  • 3.21.14. Perpetuum Basic Operating Principles Of A Vibration Energy Harvester
• 3.22. Microchip Technology Inc.
• 3.23. MicroGen Systems
• 3.24. MicroStrain
• 3.25. Nextreme Thermal Solutions
• 3.26. Patria
• 3.27. University of Michigan ISSCC
  • 3.27.1. University of Michigan Intra-Ocular Pressure Monitor (IOPM) Device Ultra-Low Power Management
  • 3.27.2. University of Michigan Intra-Ocular Pressure Monitor (IOPM) Device EH Wireless Sensor Components
  • 3.27.3. University of Michigan Intra-Ocular Pressure Monitor (IOPM) Device Building Millimeter Scale EH-Based Computers
  • 3.27.4. Permanent Power Using Cymbet Solid State Rechargeable Batteries
• 3.28. VigilX
• 3.29. MacSema
• 3.30. Omron Corp.
  • 3.30.1. Omron Photovoltaic Inverter Technology
• 3.31. Silicon Labs Solutions For Energy Harvesting Systems
  • 3.31.1. Silicon Labs Energy Harvesting Tipping Point for Wireless Sensor Applications
  • 3.31.2. Silicon Laboratories Low-Power Optimization
  • 3.31.3. Silicon Labs Solutions For Energy Harvesting Systems
  • 3.31.4. Silicon Labs Minimizing The Amount Of Time The Radio Is On
  • 3.31.5. Silicon Laboratories Managing Harvested Energy
  • 3.31.6. Silicon Labs Ability To Power Wireless Sensor Nodes
  • 3.31.7. Silicon Labs Powers Wireless Node with Energy Harvesting
• 3.32. Modern Water plc / Cymtox Limited
  • 3.32.1. Modern Water plc / Cymtox Limited
• 3.33. Schneider Electric
• 3.34. ABB
  • 3.34.1. GMZ
• 3.35. Kelk
• 3.36. Alphabet Energy
• 3.37. Perpetua
• 3.38. Phonomic Devices
• 3.39. ARPA-E Awardees $100 Million to Advance Clean Energy Technologies

4. ENERGY HARVESTING TECHNOLOGY

• 4.1. Wireless Sensor Solutions For Use In Buildings And Industrial Installations - Green. Smart. Wireless.
  • 4.1.1. Energy Harvesting Wireless Sensor Solution
  • 4.1.2. EnOcean Dolphin Interoperable System Architecture
• 4.2. Nanotechnology Graphene
  • 4.2.1. Nanoscale Semiconductor Materials:
  • 4.2.2. Nanotechnology Nanomaterials
• 4.3. Components of an Energy Harvesting System
• 4.4. Piezoelectric Devices
  • 4.4.1. Polymer Film Substrate for Thin Flexible Profile
  • 4.4.2. Comparison Of Battery Performances
• 4.5. Energy Densities
  • 4.5.1. Lithium-Ion Batteries
  • 4.5.2. Power Scavenging
  • 4.5.3. Temperature Gradients
  • 4.5.4. Human Power
  • 4.5.5. Pressure Variations
  • 4.5.6. Vibrations
• 4.6. Energy Harvesting Known As Power Harvesting Or Energy Scavenging
  • 4.6.1. Engine Coatings
  • 4.6.2. Self-Sustaining Materials
  • 4.6.3. Artificial Neural Networks
  • 4.6.4. Cloud Computing Social Networking-
• 4.7. Fabrication Of High Energy And Power Density Thin-Film Super-Capacitors
• 4.8. Silicon Carbide Substrate Market
• 4.9. Fraunhofer Institute
• 4.10. Tadiran Batteries
• 4.11. Perpetua
• 4.12. ZigBee® Alliance
• 4.13. ALD Energy Harvesting Modules
• 4.14. Advanced Cerametrics

5. ENERGY HARVESTING COMPANY PROFILES

• 5.1. ABB
  • 5.1.1. ABB and IO Deliver Direct Current-Powered Data Center Module
  • 5.1.2. ABB / Validus DC Systems DC power infrastructure equipment
• 5.2. Adaptive Materials Technology - Adaptamat Ltd
• 5.3. Alphabet Energy
  • 5.3.1. Alphabet Energy Inexpensive Waste Heat Recovery Technology
  • 5.3.2. Alphabet Thermoelectrics
• 5.4. Arrow Electronics
• 5.5. American Elements, USA
• 5.6. Avnet
• 5.7. Arveni
• 5.8. BAE Systems
  • 5.8.1. BAE Key Facts
  • 5.8.2. BAE Strategy
  • 5.8.3. BAE Operational Framework
  • 5.8.4. BAE Key Performance Indicators (KPIs)
  • 5.8.5. BAE Systems Ant Size Robot
  • 5.8.6. BAE Project Management
  • 5.8.7. BAE Engineering
  • 5.8.8. BAE Personal Robots
  • 5.8.9. BAE Systems Large UGV
  • 5.8.10. BAE Systems Plc (BAES.L) Hired Advisors To Sell Part Of Its North American Commercial Aerospace Business
• 5.9. Boeing
  • 5.9.1. Boeing Automated Identification Technology (AIT)
  • 5.9.2. Boeing Structural Health Monitoring
  • 5.9.3. Boeing Aircraft Health Monitoring
  • 5.9.4. Boeing
  • 5.9.5. Boeing 787 Dreamliner
  • 5.9.6. Boeing 787 Dreamliner Performance
  • 5.9.7. Boeing Advanced Technology
  • 5.9.8. Boeing Participation In Commercial Jet Aircraft Market
  • 5.9.9. Boeing Participation In Defense Industry Jet Aircraft Market
  • 5.9.10. Boeing Defense, Space & Security
  • 5.9.11. Boeing Advanced Military Aircraft:
  • 5.9.12. Boeing Military Aircraft
  • 5.9.13. Boeing Continuing Progress
  • 5.9.14. Boeing-iRobot Team Receives New SUGV Task Order From US Army
• 5.10. CST
• 5.11. Cymbet
  • 5.11.1. Cymbet Team:
  • 5.11.2. Cymbet Investors:
  • 5.11.3. Cymbet Investors
  • 5.11.4. Cymbet Partners, Sales and Distribution:
  • 5.11.5. Cymbet Manufacturing:
  • 5.11.6. Cymbet to Open World's Highest Volume Solid-State Battery Manufacturing Facility
  • 5.11.7. Cymbet Partnering with X-FAB
  • 5.11.8. Cymbet / X-FAB, Inc.
  • 5.11.9. Cymbet Expanding in Minnesota
  • 5.11.10. Cymbet / LEDA
  • 5.11.11. Distribution Agreement EnerChip™ Eco-Friendly Solid State Batteries
  • 5.11.12. Cymbet EVAL-09 Utilizes Harnessing Ambient Energy
  • 5.11.13. Cymbet Secures $31 Million in Private Financing
• 5.12. Digi International
  • 5.12.1. Digi International Revenue
  • 5.12.2. Digi International Business Highlights:
• 5.13. Dust Networks
  • 5.13.1. Dust Networks Self-Powered IPV6 Wireless Sensor Network
• 5.14. EnOcean GmbH
  • 5.14.1. EnOcean Technology
• 5.15. Finmeccanica
  • 5.15.1. Finmeccanica / SELEX Galileo
  • 5.15.2. SELEX Galileo Inc.
  • 5.15.3. SELEX Galileo Technologies
• 5.16. Flexible Electronics Concepts
• 5.17. Ferro Solutions
  • 5.17.1. Ferro Solutions
• 5.18. Fraunhofer Institute for Integrated Circuits IIS
• 5.19. General Electric Company
  • 5.19.1. GE Energy Wireless Condition Monitoring System / Perpetuum Electromagnetic Vibration Energy Harvesting Device
  • 5.19.2. GE HabiTEQ Systems and EnOcean Energy-Harvesting Technology Joint Venture
  • 5.19.3. General Electric / EnOcean Equipped Devices Sensors Fit In Ultra-Thin Switches On Glass Panels
  • 5.19.4. GE Smart Energy Technologies
• 5.20. GMZ
• 5.21. Honeywell
  • 5.21.1. Honeywell Energy-Harvesting Sensing and Control
• 5.22. Infinite Power Solutions
  • 5.22.1. Infinite Power Solutions Solid-State, Thin-Film Batteries
  • 5.22.2. Infinite Power Solutions Micro-Energy Storage Devices
  • 5.22.3. Infinite Power Solutions Battery Applications
  • 5.22.4. Infinite Power Solutions And Tokyo Electron Device Global Distribution Agreement
  • 5.22.5. Infinite Power Solutions Raises $20.0m In Series C Financing
• 5.23. Inventec
• 5.24. IO
• 5.25. ITN Lithium Technology
  • 5.25.1. ITN's Lithium EC sub-Division Focused On Development And Commercialization of EC
  • 5.25.2. ITN's SSLB Division Thin-Film Battery Technology
  • 5.25.3. ITN Lithium Air Battery
  • 5.25.4. ITN Fuel Cell
  • 5.25.5. ITN Thin-film Deposition Systems
  • 5.25.6. ITN Real Time Process Control
  • 5.25.7. ITN Plasmonics
• 5.26. II-VI incorporated / Marlow Industries
  • 5.26.1. II-VI Incorporated (NASDAQ: IIVI)
  • 5.26.2. II-VI Incorporated / Marlow Infrared And Near-Infrared Laser Optical Elements
  • 5.26.3. II-VI incorporated / Marlow Markets
• 5.27. KCF Technologies Inc
• 5.28. Kelk
• 5.29. Levant Power
• 5.30. Micropelt
• 5.31. Millennial Net
  • 5.31.1. Millennial Net Wireless Sensor Network:
  • 5.31.2. Millennial Net's MeshScape GO WSN Technology
• 5.32. Modern Water
• 5.33. Nature Technology
• 5.34. Nextreme
• 5.35. Northrop Grumman
  • 5.35.1. Northrop Grumman Smart Grid
  • 5.35.2. Northrop Grumman
  • 5.35.3. Northrop Grumman Corp (NOC.N) Spinning Off Or Selling Its Shipbuilding Business
  • 5.35.4. Northrop Grumman Remotec Robots
  • 5.35.5. Northrop Grumman Opens New Facilities for Design and Manufacture of Unmanned Ground Vehicles in Coventry
  • 5.35.6. Northrop Grumman Business Sectors:
  • 5.35.7. Northrop Grumman Aerospace Systems
• 5.36. OMRON
  • 5.36.1. Omron Revenue
• 5.37. Planar Energy Devices
  • 5.37.1. DOE Selects Planar Energy for Oak Ridge National Laboratory Collaborative R&D Program to Advance Next-Generation Battery Development
• 5.38. Perpetua
• 5.39. Perpetuum
  • 5.39.1. Perpetuum Alliances
• 5.40. Phononic Devices
• 5.41. Polatis Photonics
  • 5.41.1. Polatis Technology and Products
• 5.42. PS
• 5.43. ReVolt Technology
  • 5.43.1. Executives of BMW and Gould Join ReVolt's Advisory Leadership Team
• 5.44. Teledyne / Rockwell Scientific
• 5.45. Severn Water / Modern Water / Cymtox Limited
• 5.46. Silicon Labs
  • 5.46.1. Silicon Laboratories Energy Harvesting Applications
• 5.47. Schneider Electric
• 5.48. Syngenta Sensors UIC
• 5.49. Texas Instruments (TXN:NYSE)
  • 5.49.1. Texas Instruments
• 5.50. Trophos Energy
• 5.51. University of California, Berkeley
• 5.52. University of Michigan
  • 5.52.1. University of Michigan's Department of Electrical Engineering and Computer Science Nano-Thin Sheets Of Metal
• 5.53. Zarlink Semiconductor AB
• 5.54. US Department of Energy's Advanced Research Projects Agency-Energy (ARPA-E) Seed Funding
• 5.55. Selected Energy Harvesting Market Participants

Energy Harvesting Executive Summary

• Table ES-1: Energy Harvesting And Energy Storage Market Factors
• Table ES-2: Energy Harvesting Market Driving Forces
• Table ES-3: Energy Harvesting Wireless Network Applications
• Figure ES-4: Energy Harvesting Market Shares, Dollars, First Three Quarters 2011
• Figure ES-5: Energy Harvesting Sensor Network Shipments, Market Forecasts Dollars, Worldwide, 2012-2018

Energy Harvesting WinterGreen Research Opinion

• Table 1: Challenges In Battery And Energy Harvesting System Design

Energy Harvesting Market Description and Market Dynamics

• Table 1-1: Smarter Planet Sensor Network Systems Functions
• Figure 1-2: Energy Harvesting Circuit Board
• Figure 1-3: Energy Harvesting on Bear Sensor
• Table 1-4: Energy Harvesting Applications
• Table 1-5: Common Sources of Energy Harvesting
• Table 1-6: Components of an Energy Harvesting System
• Figure 1-7: IBM WebSphere Application Server Implements Smarter Computing
• Table 1-8: Energy Harvesting Target Markets
• Table 1-9: Principal Features Used To Compare Rechargeable Batteries
• Table 1-10: Challenges in Battery and Energy Harvesting System Design
• Figure 1-11: BMW's Mini E Electric Car Powered By A Rechargeable Lithium-Ion Battery
• Table 1-12: Examples of Hybrid Electric Vehicles
• Figure 1-13: Typical Structure Of A Thin Film Solid State Battery

Energy Harvesting Market Shares and Market Forecasts

• Table 2-1: Energy Harvesting And Energy Storage Market Factors
• Table 2-2: Energy Harvesting Market Driving Forces
• Table 2-3: Energy Harvesting Wireless Network Applications
• Figure 2-4: Energy Harvesting Market Shares, Dollars, First Three Quarters 2011
• Table 2-5: Energy Harvesting Market Shares, Vibration, Piezoelectric, Thermoelectric, Magnetic, Dollars, Worldwide, First Three Quarters 2011
• Table 2-6: Perpetua Energy Harvesting Applications
• Figure 2-7: Perpetuum Markets Served By Industry
• Figure 2-8: Perpetuum ROI Addresses The Hidden Costs Of Under Monitored Assets
• Figure 2-9: Perpetuum Estimates Number of BOP Machine Assets Under Monitored Exceeds 70%
• Table 2-10: IBM Positions To Support Sensor Networks
• Figure 2-11: IBM Describes Smarter Plant Solutions Impact on IT
• Figure 2-12: IBM Strategic Vision for Innovation
• Table 2-13: Leading Energy Harvesting Market Participants by Technology
• Figure 2-14: Energy Harvesting Sensor Network Shipments, Market Forecasts Dollars, Worldwide, 2012-2018
• Figure 2-15: Energy Harvesting Sensor Network Shipments, Market Forecasts Dollars, Worldwide, 2012-2018
• Figure 2-16: Smart City Energy Harvesting Shipments Market Forecasts, Dollars, Worldwide, 2012-2018
• Figure 2-17: Smarter Computing Depends on Instrumented Devices
• Figure 2-18: Transportation Rail and Electric Vehicle Energy Harvesting Market Forecasts Dollars, Worldwide, 2012-2018
• Figure 2-19: Number and Floor Space of US Commercial Buildings
• Figure 2-20: Energy Use Intensity for LEED Certified Buildings (kBtu per Square Foot)
• Figure 2-21: Smart Building Energy Harvesting Shipments Market Forecasts, Worldwide, Dollars, 2012-2018
• Figure 2-22: Contractors And Construction Energy Harvesting Shipments Market Forecasts, Worldwide, Dollars, 2012-2018
• Figure 2-23: Smart Grid Meter Energy Harvesting Market Forecasts Dollars, Worldwide, 2012-2018
• Figure 2-24: Smart Grid Substation Energy Harvesting Shipments, Market Forecasts, Worldwide, 2012-2018
• Figure 2-25: Airline / Space / Defense Industry Energy Harvesting Market Forecasts, Dollars, Worldwide, 2012-2018
• Figure 2-26: Border and Perimeter Security Energy Harvesting Shipments Market Forecasts, Dollars, Worldwide, 2012-2018
• Table 2-27: Energy Harvesting Market Industry Segments, Percent, Worldwide, 2012 -2018
• Table 2-28: Energy Harvesting Market Industry Segments, Percent, Worldwide, 2012 -2018
• Figure 2-29: Energy Harvesting Market Industry Segments, Units, Worldwide, 2012-2018
• Table 2-30: Energy Harvesting Market Industry Segments, Units, Worldwide, 2012-2018
• Figure 2-31: Marlow Energy Harvesting Device Price
• Figure 2-32: Nextreme Energy Harvesting Modules WPG-1 WRLES PWR GEN 1mW 3.3, 4.1 OR 5V
• Figure 2-33: MicroPelt Energy Harvester
• Figure 2-34: Thin Film and Printed Battery Market Shares, Dollars, 2010
• Table 2-35: Thin Film and Printed Battery Market Shares, Dollars, Worldwide, 2010 and First Three Quarters 2011
• Figure 2-36: Thin Film and Printed Battery Markets Forecasts Dollars, Worldwide, 2011-2017
• Table 2-37: Thin Film and Printed Battery Market Forecasts Dollars, Worldwide, 2011-2017
• Table 2-38: Thin Film and Printed Battery Markets Forecasts Dollars, Worldwide, 2011-2017
• Table 2-39: Thin Film and Printed Battery Market Industry Segments, Percent, Worldwide, 2011-2017
• Figure 2-40: Smarter Computing Depends on Instrumented Devices
• Figure 2-41: Smarter Planet Impact on IT
• Table 2-42: Advantages Offered by SOA
• Table 2-41: Thin Film Battery Market Driving Forces
• Table 2-42: Smarter Computing Market Driving Forces
• Table 2-43: Thin Film Battery Benefits
• Table 2-44: Comparison Of Battery Performance
• Figure 2-45: Thin Film Battery Energy Density
• Figure 2-46: Silver Nanoplates
• Table 2-47: Energy Harvesting Regional Market Segments, Dollars, First Three Quarters 2011
• Table 2-48: Energy Harvesting Regional Market Segments, 2010

Energy Harvesting Product Description

• Figure 3-1: Marlow Industries Evergen
• Table 3-2: Marlow Industries Evergen Energy Harvesting Solutions
• Figure 3-3: Micropelt Thermoharvester
• Figure 3-4: EnOcean ECO 100 - Motion Energy Harvesting
• Table 3-5: EnOcean Energy Harvesting Motion Converter
• Table 3-6: EnOcean Thermo Converter
• Table 3-7: EnOcean Energy Converters For Energy Harvesting Wireless Applications
• Figure 3-8: EnOcean-Enabled Wireless Sensor Networks
• Table 3-9: EnOcean Alliance Energy Harvesting Solutions Advantages
• Table 3-10: EnOcean Energy Harvesting Sources
• Figure 3-11: EnOcean Energy Harvesting Wireless Sensor Technology
• Figure 3-12: EnOcean Energy Harvesting Wireless Sensor Devices
• Figure 3-13: Arveni Wireless Sensor
• Table 3-14: Arveni Micro Generator Features
• Table 3-15: Boeing Energy Harvesting Development Programs Functions
• Figure 3-16: Broadband Energy Harvester (Boeing )
• Figure 3-17: Broadband Energy Harvester (Boeing )
• Figure 3-18: Ferro Solutions Wireless Sensor Network
• Table 3-19: KCF Technologies Energy Harvesting Wireless Sensors Offered
• Figure 3-20: KCF Technologies Smart Rod End for Wireless Monitoring of Helicopter Rotor Components
• Figure 3-21: KCF Technologies Rotor Energy Harvesting Devices
• Figure 3-22: KCF Technologies Harvester-Powered Wireless Accelerometers
• Table 3-23: KCF Technologies Wireless Vibration Sensors for Shipboard Environments
• Figure 3-24: KCF Technologies Harvester-Powered Wireless Sensors for Industrial Machine Monitoring
• Table 3-25: KCF Technologies Energy Harvesting Devices
• Table 3-26: KCF Technologies Piezoelectric Devices
• Figure 3-27: KCF Technologies Compact Narrowband High- Acoustic Sound Source
• Figure 3-28: KCF Technologies Liquid Atomization and Dispensing
• Figure 3-29: KCF Technologies Extreme Amplitude Piezoelectric Noise Source for HUMVEE Air Filter Cleaning
• Table 3-30: Trophos Energy Marine Applications
• Table 3-31: Trophos Energy Land Applications
• Figure 3-32: Trophos Energy innovative Marine, Land, and Electrocics Power Generation Products
• Figure 3-33: MIT Energy Harvesting Device Converts Low-Frequency Vibrations Into Electricity
• Table 3-34: Linear Technology Comprehensive Line Of High Performance Battery
• Figure 3-35: ReVolt TechnologieszFab Battery
• Table 3-36: ReVolt Button Cell Air Electrode
• Table 3-37: ReVolt Technology Partnership With BASF:Target Markets
• Table 3-38: Cymbet Solid State Energy Storage Energizing Innovation Target Markets
• Table 3-39: Cymbet Solid State Energy Storage products
• Table 3-40: Cymbet EnerChip™ Solid-State Product Line
• Table 3-41: Cymbet's EnerChip Benefits
• Figure 3-42: Cymbet EnerChip CBC3105-BDC:
• Table 3-43: Cymbet EnerChip CBC001-BDC:Target Markets
• Table 3-44: Cymbet Energy Harvesting Applications
• Table 3-45: Infinite Power Solutions THINERGY® Product Family
• Table 3-46: Infinite Power Solutions, Inc. Maxim Energy Management Chips
• Table 3-47: Infinite Power Solutions, Inc. Applications For Energy Harvester
• Table 3-48: Infinite Power Solutions Charging Methods
• Table 3-49: Wireless Sensor Network Applications
• Figure 3-50: Planar Energy's Solid State Batteries Spraying Materials Onto A Metal Substrate
• Table 3-51: Applications Powered By PMG Rail
• Table 3-52: Perpetuum Condition Monitoring Technologies
• Table 3-53: Perpetuum Business Benefit To Dominate The Industrial Maintenance Scene
• Figure 3-54: Perpetuum Vibration Energy-Harvesting Wireless Sensor Node Components And Structure
• Figure 3-55: Perpetuum Switch Mode Efficiency
• Figure 3-56: Perpetuum Condition Assessment Need
• Figure 3-57: Perpetuum Condition Assessment Principle of Operation
• Figure 3-58: Perpetuum Vibration Energy Harvesting for Rail Cars
• Figure 3-59: Perpetuum Vibration Energy Harvesting for Rail Wheels and Bearings
• Figure 3-60: Perpetuum Temperature Variation Energy Harvesting for Rail Wheels and Bearings
• Figure 3-61: Perpetuum Temperature Variation and Vibration Energy Harvesting Wireless Network Solution
• Figure 3-62: Perpetuum Vibration Energy Harvesting Solution Benefits
• Figure 3-63: Perpetuum Energy Harvesting ROI for Ten Years
• Figure 3-64: Perpetuum Energy Harvesting Current Produced
• Figure 3-65: Perpetuum Energy Harvesting Power Measurement
• Figure 3-66: Perpetuum Energy Harvesting Wireless Monitoring
• Figure 3-67: Perpetuum Energy Harvesting Installation
• Figure 3-68: Perpetuum Energy Harvesting Innovation Solutions
• Figure 3-69: Perpetuum Energy Free Standing Harvesting Development Kit
• Figure 3-70: Perpetuum Energy Harvesting Wireless Monitoring and Automation
• Figure 3-71: Perpetuum Energy Harvesting of Under Monitored BOP Assets
• Figure 3-72: Perpetuum Power Output Spectrum
• Figure 3-73: Perpetuum Vibration Energy Harvester powering the Wireless Sensor Node
• Figure 3-74: Perpetuum Vibration Energy Harvesters
• Figure 3-75: Perpetuum Power Solutions for Wireless Monitoring and Automation:
• Table 3-76: Perpetuum Vibration Energy Harvester (VEH) Functions
• Figure 3-77: Perpetuum Vibration Energy Harvester
• Table 3-78: Perpetuum Industrial Markets Served
• Figure 3-79: Perpetuum Markets Served By Industry
• Figure 3-80: Perpetuum ROI Addresses The Hidden Costs Of Under Monitored Assets
• Figure 3-81: Perpetuum Estimates Number of BOP Machine Assets Under Monitored Exceeds 70%
• Figure 3-82: Perpetuum Assessment of Machine Assets Under Monitored
• Table 3-83: MicroGen Systems Leveraging of Factors Converging To Open Up Opportunity In Energy Harvesting
• Table 3-84: MicroGen Systems Energy Harvesting For Battlefield
• Figure 3-85: University of Michigan Intra-Ocular Pressure Monitor (IOPM) Device Wireless Sensor Basic Elements
• Table 3-86: Silicon Labs Solutions For Energy Harvesting Applications
• Table 3-87: Silicon Labs Solutions For Energy Harvesting Solutions
• Table 3-88: Silicon Labs Solutions For Energy Harvesting Systems
• Figure 3-89: Silicon Laboratories Wireless Sensor Node Power Cycle
• Figure 3-90: Silicon Labs Solutions For Energy Harvesting Systems
• Figure 3-91: Schneider Electric Energy Harvesting
• Figure 3-92: Perpetua Renewable Energy Source for Wireless Sensors
• Figure 3-93: Perpetua Renewable Energy Source Applications
• Figure 3-94: Perpetua Energy Harvesting Device
• Table 3-95: Perpetua Thermoelectric Technology Key Differentiating Features
• Figure 3-96: Perpetua Technology

Energy Harvesting Technology

• Figure 4-1: Energy Harvesting Wireless Sensor Technology
• Figure 4-2: : Energy Harvesting Wireless Sensor Solution
• Figure 4-3: EnOcean Dolphin Interoperable System Architecture
• Table 4-4: Energy Harvesting Modules Functions
• Figure 4-5: Graphene Nanostructure
• Figure 4-6: Piezoelectric Devices
• Table 4-7: Smarter Computing Market Driving Forces
• Table 4-8: Thin Film Battery Benefits
• Table 4-9: Comparison Of Battery Performance
• Figure 4-10: Thin Film Battery Energy Density
• Figure 4-11: Comparison of Power Density of Energy Harvesting Methods/
• Figure 4-12: Perpetua Flexible Thermoelectric Film
• Figure 4-13: Perpetua Technology

Energy Harvesting Company Profiles

• Table 5-1: ABB Product Launches
• Figure 5-2: Alphabet Energy Heat To Electricity Examples
• Figure 5-3: Arveni Wireless Sensor Block Diagram
• Table 5-4: ARVENI's Microgenerators Systems Functions
• Figure 5-5: BAE Military Robot in Development
• Figure 5-6: Boeing Vulture technology
• Table 5-7: Boeing Military Aircraft Key programs
• Table 5-8: Boeing Unmanned Airborne Systems:
• Table 5-9: Boeing Weapons:
• Table 5-10: CST Target Markets
• Table 5-11: Selected Enocean Shareholders:
• Figure 5-12: Ferro Solutions Energy Harvesters And Sensors
• Figure 5-13: Ferro Solutions Energy Harvesters And Sensors Target Markets
• Table 5-14: Ferro Solutions Selected Clients
• Table 5-15: Ferro Solutions Energy Harvester Uses
• Table 5-16: Ferro Solutions FS Energy Harvester Industrial & Process Automation and Utilities
• Table 5-17: Honeywell Energy-Harvesting Sensing and Control
• Table 5-18: ITN Technologies
• Figure 5-19: ITN Thin Film Battery Technology
• Figure 5-20: ITN Battery
• Figure 5-21: ITN Thin-Film Deposition Systems
• Figure 5-22: ITN's Thin-Film Deposition Systems
• Table 5-23: ITN Thin-Film Deposition Systems Products and Services Offered
• Table 5-24: ITN Thin-Film Deposition Systems
• Figure 5-25: ITNIYN Fuel Cells
• Table 5-26: KCF Technologies Core Technical Focus Areas
• Table 5-27: Kelk Recent Orders
• Table 5-28: Millennial Net's MeshScape System Functions
• Table 5-29: MeshScape GO Deployment Components:Omron Revenue
• Figure 5-30: Perpetua Renewable Energy Solutions For Wireless Sensors
• Figure 5-31: Perpetua Energy Harvesting Product Set
• Table 5-32: Perpetua's Thermoelectric Technology Features
• Table 5-33: Trophos Energy Harvesting Power Solutions Applications

Press Release

預計2018年時環境發電市場將達到51億美元

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