エレクトロニクスにおけるバッテリー廃止。マーケットインパクト IoT, 6G, Healthcare, Wearables 2021-2041
Battery Elimination in Electronics: Market Impact IoT, 6G, Healthcare, Wearables 2021-2041
IDTechExのレポート「Battery Elimination in Electronics(電子機器におけるバッテリー廃止)」では、主要な企業や技術を詳細に調査・分析しています。
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IDTechExのレポート「Battery Elimination in Electronics(電子機器におけるバッテリー廃止)」では、主要な企業や技術を詳細に調査・分析しています。
主な掲載内容(目次より抜粋)
-
全体概要および結論
-
市場予測
-
はじめに
-
ヘルスケアとウェアラブル
-
IOT、SRWN、LPWAN バッテリー消去
Report Details
In numbers, most wireless electronics is already battery-free yet portable. Much more is on the way as detailed in the unique new analysis by IDTechEx report, "Battery Elimination in Electronics: Market Impact IoT, 6G, Healthcare, Wearables 2021-2041". Covering over 150 organisations in 300 pages, the scope is unprecedented. Few markets go from under $8 billion to over $120 billion in 2041. This one does.
Learn how researchers are progressing no less than four routes to the batteryless implanted heart pacemaker and defibrillator eliminating battery-driven deaths. Triboelectricity, piezoelectricity, electrodynamics and RF wireless energy transfer are in the frame. One lab has a battery-free optogenics device to control neuronal activation. Meanwhile, in addition to a cool 127 billion backscatter RFID and anti-theft tags being deployed without batteries this year, an increasing variety of companies have battery-free in their strapline. For instance, Thrive and Battery-Free both trumpet "battery-free wearables".
For safety and reliability, you can buy battery-free airman's headphones or boat telephones and oxygen and carbon monoxide sensors. In Africa, batteryless lights, radio and foetal heart monitors are charged by rotating a crank or pulling. Pedal a computer.
It is just a beginning. India and China have launched electrostatic facemasks that destroy bacteria and viruses and grab particulates with triboelectrics replacing the battery meaning no pollution on disposal and lower cost. Potential is billions. The world will need 100 million battery-free continuous glucose sensors yearly for the diabetes epidemic. That will be unusual progress beyond a similar yearly number of perpetual piezoelectric gas lighters.
"No wires, no batteries, no limits" is throughout the EnOcean Alliance with 4000 inter-operable eco-system options for smart homes, buildings and spaces based on the maintenance-free radio standard (ISO/IEC 14543-3-10/11). See them in over one million buildings already - the most widespread and most field-tested wireless building automation standard in the world.
The new IDTechEx report explains how more-advanced wireless energy transfer WET, multi-mode energy harvesting and supercapacitors will take things much further. Additionally, 6G Communications around 2030 promises instant massive data to and from unpowered devices and even charging your supercapacitor smartphone from its signal beams. Others demonstrate battery-free cellphones by other routes. Combine such batteryless technologies and even grander achievements are possible. Flexible harvesting on supercapacitor layers gets them into stranger places.
The report is commercially oriented and easily grasped with large numbers of new infograms, pictures, graphs, interviews and comparison tables. Prepared by PhD level analysts across the world, many of whom have studied these subjects for over 20 years, it answers such questions as:
-
Why is there more urgency to replace batteries and in what sectors?
-
Situation in Healthcare, Communications, Personal Electronics, Third World, IoT, other?
-
Benefits, including enhanced safety, even saving lives?
-
Opportunities from the fit-and-forget trend?
-
Toolbox of 6G Communications WIET, WET, next energy harvesting, biofuelcells, supercapacitors?
-
Where will they be combined and why the pivot to triboelectrics, multimode flexible etc.?
-
How, when for battery-free implants, continuous glucose monitors, smartwatches, cellphones, IoT?
-
Technology, standards and adoption roadmaps 2021-2041?
-
Market sizes 2021-2041?
-
What does the research pipeline tell us?
The Executive Summary and Conclusions is a quick read for those in a hurry, giving 13 key conclusions with all the trends and possibilities compared and 34 examples including lessons of a pictured cellphone and IoT teardown. See best harvesting technologies, 6G, supercapacitor and device roadmaps 2021-2041. The 40 forecasts of Chapter 2 are mostly calculated by IDTechEx. The Introduction consolidates needs, trends, options, methodology (6 routes), new focus and new toolbox to batteryless with nine examples. Consideration ranges from LPWAN to virus-destroying electrostatic facemasks and Samsung smartphone styluses.
The deep dive then begins with a chapter on Healthcare and Wearables - 20 packed pages including 20 examples, four routes to battery-free embedded heart assistance, triboelectric and biofuelcell breakthroughs, future. Learn why harvesting lower frequency "infrasound" is better than vibration harvesting for all wearables. Chapter 5 is IoT, SRWN such as Bluetooth, LPWAN battery elimination, 22 pages of comparisons, examples, predictions, possibilities. IoT is seriously assessed, distinguishing cynical renaming of existing things from genuinely new business that will be enabled by battery elimination.
Chapter 6 covers 6G Communications' promised Wireless Information and Energy Transfer WIET eliminating batteries. It has 12 packed pages of new infograms, tables, pictures. See how 5G and 6G fit in, the appraisal again being critical not adulation. Chapter 7 assesses the six routes to batteryless cellphones and wearables with such things as six harvesting cost projections, device power projections, combinational options, WET, the University of Washington battery-free cellphone and HD video streaming in seven pages. Chapter 8, 11 pages, is battery elimination by Wireless Energy Transfer WET to RFID and NFC, a huge success already, and potentially one in Real Time Locating Systems RTLS, the new 6G Communications promising breakthrough.
Chapter 9 "Eliminating batteries from building controls" takes 22 pages to compare technologies and opportunities with many examples detailed and big names NEC, Toshiba, Yamaha, ABB, Siemens. Chapters 10 and 11 are exceptionally long and thorough examinations of the principal tools of battery elimination - energy harvesting and supercapacitors both experiencing radical change, new options and variants and improvement in 2020/2021. Only the IDTechEx report, ""Battery Elimination in Electronics: Market Impact IoT, 6G, Healthcare, Wearables 2021-2041" has this latest news and insight, essential in such a fast-moving subject.
ページTOPに戻る
目次
|
1. |
EXECUTIVE SUMMARY AND CONCLUSIONS |
|
1.1. |
Purpose of this report |
|
1.2. |
Top ten electronic devices by number |
|
1.3. |
Top ten electronic devices by power choices and issues |
|
1.4. |
Some reasons for eliminating small batteries by application |
|
1.5. |
Batteryless is a strong selling point |
|
1.6. |
Thirteen key conclusions |
|
1.7. |
Energy harvesting options to power electronic and small electric devices |
|
1.8. |
Promising future applications by preferred energy harvesting technology - examples |
|
1.9. |
Example of battery issues: |
|
1.10. |
LPWAN/ IOT node teardown and battery elimination |
|
1.10.1. |
Battery cost share |
|
1.10.2. |
IoT battery elimination example March 2021 |
|
1.11. |
Roadmap for electronic device harvesting 2021-2041 |
|
1.12. |
6G Communications roadmap to battery elimination 2021-2041 |
|
1.13. |
Supercapacitor and device roadmap of battery elimination in electronics 2021-2041 |
|
2. |
MARKET FORECASTS |
|
2.1. |
Wireless electronics and small electric devices without batteries by type 2021 and 2041 |
|
2.2. |
Wireless electronics and small electric devices without batteries % $billion by sector 2041 |
|
2.3. |
IoT LPWAN connections |
|
2.4. |
Bluetooth device forecasts |
|
2.5. |
RFID forecasts |
|
2.6. |
Energy harvesting for electronics battery and batteryless forecasts |
|
2.6.1. |
Summary and roadmap 2020-2040 |
|
2.6.2. |
Photovoltaic energy harvesting for electronics: units, unit price, market value 2020-2040 |
|
2.6.3. |
Thermoelectric energy harvesting transducers by application number, price, market value 2019-2030 |
|
2.6.4. |
Piezoelectric energy harvesting for electronics: number, price, market value 2020-2030 |
|
2.6.5. |
Triboelectric transducer and self-powered sensors 2020-2040 $ million |
|
2.6.6. |
Electrodynamic energy harvesting for electronics: number, price, market value 2020-2040 |
|
2.7. |
Forecast for pico products (flashlights, lanterns etc) battery and batteryless with integral harvesting |
|
2.8. |
Global supercapacitor market by application |
|
2.8.1. |
$ billion 2021-2041 with 10 top suppliers' sales |
|
2.8.2. |
Global supercapacitor value market by territory 2021-2041 |
|
2.8.3. |
Earliest major adopter of supercapacitor advances by territory/ application 2021-2041 |
|
2.8.4. |
Continuous glucose monitoring CGM in context $ million to 2029 |
|
2.9. |
6G smartphones and total cellphones 2021-2041 |
|
3. |
INTRODUCTION |
|
3.1. |
Overview |
|
3.2. |
Power needed by electronics and small electrical devices |
|
3.3. |
Battery problems and alternatives |
|
3.4. |
Drivers and facilitators of battery elimination |
|
3.4.1. |
How it becomes more necessary and easier |
|
3.4.2. |
Rapid improvement in alternatives and more of them |
|
3.4.3. |
How to improve, shrink and eliminate batteries |
|
3.4.4. |
Principles of batteryless operation |
|
3.4.5. |
Battery Eliminator Circuits BEC |
|
3.5. |
Energy harvesting for devices |
|
3.5.1. |
Some options compared |
|
3.5.2. |
Example of harvesting ambient RF |
|
3.5.3. |
Example of thermoelectric harvesting: KCF Technologies |
|
4. |
HEALTHCARE AND WEARABLES |
|
4.1. |
Overview |
|
4.2. |
Harvesting acoustic movement: infrasound not vibration |
|
4.2.1. |
More efficient electrodynamic harvesting with mechanical storage |
|
4.2.2. |
Kinetic energy harvesters without the need of a battery |
|
4.3. |
Batteryless implanted pacemaker examples |
|
4.3.1. |
Triboelectric motion harvesting |
|
4.3.2. |
Piezoelectric and triboelectric |
|
4.3.3. |
Electrodynamic |
|
4.3.4. |
RF powered |
|
4.4. |
Batteryless from both feet |
|
4.5. |
Near-field-enabled clothing sensors |
|
4.6. |
Battery-free patch monitoring by optical power transfer |
|
4.7. |
Perspiration-powered e-skin for multiplexed wireless sensing |
|
4.8. |
Batteryless e-textile bioenergy microgrid |
|
4.9. |
Smart bandage battery-free |
|
4.10. |
Two batteryless triboelectric facemasks activated by breathing |
|
4.11. |
Thermoelectric battery-free wearables |
|
4.12. |
Wind-up foetal heart monitor |
|
4.13. |
Portal Instruments batteryless needle-free jet injection platform |
|
5. |
IOT, SRWN, LPWAN BATTERY ELIMINATION |
|
5.1. |
Overview |
|
5.2. |
The IoT problem |
|
5.3. |
Area wireless networks |
|
5.4. |
Cost challenge to sell billions yearly: what learning curves predict |
|
5.5. |
Trameto multimode battery-free IoT |
|
5.6. |
IoT node compromises assist |
|
5.7. |
Smaller, lighter photovoltaic IoT node |
|
5.8. |
Matrix thermoelectric power for IoT |
|
5.9. |
21 LPWAN silicon manufacturers - partners for IoT |
|
5.10. |
Smart metering |
|
5.11. |
RFID sensors |
|
5.12. |
Reality Checking the IOT story |
|
5.13. |
Industry 4.0 worldwide |
|
5.14. |
Cognitive buildings |
|
6. |
6G COMMUNICATIONS WIET ELIMINATING BATTERIES |
|
6.1. |
Overview |
|
6.2. |
Parasitic power from human RF emissions |
|
6.3. |
Cards, wireless sensors and RFID parasitically powered from 5G |
|
6.4. |
6G communications reducing and eliminating batteries |
|
6.4.1. |
Overview |
|
6.4.2. |
6G wireless information and energy transfer WIET |
|
6.4.3. |
6G progress |
|
6.4.4. |
The case against 6G |
|
6.4.5. |
6G roadmap 2021-2041 |
|
7. |
SIX ROUTES TO BATTERYLESS CELLPHONES AND WEARABLES |
|
7.1. |
Routes to batteryless energy independent wearables 2031 |
|
7.2. |
Ressence Model 2 and Swatch |
|
7.3. |
Batteryless energy independent smartphones 2036 |
|
7.3.1. |
Overview of six routes |
|
7.3.2. |
Battery-free cellphone using ambient light or RF |
|
7.4. |
Towards Battery-Free HD Video Streaming |
|
8. |
BATTERY ELIMINATION BY WET TO RFID, NFC, RTLS |
|
8.1. |
ページTOPに戻る
Summary
IDTechExのレポート「Battery Elimination in Electronics(電子機器におけるバッテリー廃止)」では、主要な企業や技術を詳細に調査・分析しています。
主な掲載内容(目次より抜粋)
-
全体概要および結論
-
市場予測
-
はじめに
-
ヘルスケアとウェアラブル
-
IOT、SRWN、LPWAN バッテリー消去
Report Details
In numbers, most wireless electronics is already battery-free yet portable. Much more is on the way as detailed in the unique new analysis by IDTechEx report, "Battery Elimination in Electronics: Market Impact IoT, 6G, Healthcare, Wearables 2021-2041". Covering over 150 organisations in 300 pages, the scope is unprecedented. Few markets go from under $8 billion to over $120 billion in 2041. This one does.
Learn how researchers are progressing no less than four routes to the batteryless implanted heart pacemaker and defibrillator eliminating battery-driven deaths. Triboelectricity, piezoelectricity, electrodynamics and RF wireless energy transfer are in the frame. One lab has a battery-free optogenics device to control neuronal activation. Meanwhile, in addition to a cool 127 billion backscatter RFID and anti-theft tags being deployed without batteries this year, an increasing variety of companies have battery-free in their strapline. For instance, Thrive and Battery-Free both trumpet "battery-free wearables".
For safety and reliability, you can buy battery-free airman's headphones or boat telephones and oxygen and carbon monoxide sensors. In Africa, batteryless lights, radio and foetal heart monitors are charged by rotating a crank or pulling. Pedal a computer.
It is just a beginning. India and China have launched electrostatic facemasks that destroy bacteria and viruses and grab particulates with triboelectrics replacing the battery meaning no pollution on disposal and lower cost. Potential is billions. The world will need 100 million battery-free continuous glucose sensors yearly for the diabetes epidemic. That will be unusual progress beyond a similar yearly number of perpetual piezoelectric gas lighters.
"No wires, no batteries, no limits" is throughout the EnOcean Alliance with 4000 inter-operable eco-system options for smart homes, buildings and spaces based on the maintenance-free radio standard (ISO/IEC 14543-3-10/11). See them in over one million buildings already - the most widespread and most field-tested wireless building automation standard in the world.
The new IDTechEx report explains how more-advanced wireless energy transfer WET, multi-mode energy harvesting and supercapacitors will take things much further. Additionally, 6G Communications around 2030 promises instant massive data to and from unpowered devices and even charging your supercapacitor smartphone from its signal beams. Others demonstrate battery-free cellphones by other routes. Combine such batteryless technologies and even grander achievements are possible. Flexible harvesting on supercapacitor layers gets them into stranger places.
The report is commercially oriented and easily grasped with large numbers of new infograms, pictures, graphs, interviews and comparison tables. Prepared by PhD level analysts across the world, many of whom have studied these subjects for over 20 years, it answers such questions as:
-
Why is there more urgency to replace batteries and in what sectors?
-
Situation in Healthcare, Communications, Personal Electronics, Third World, IoT, other?
-
Benefits, including enhanced safety, even saving lives?
-
Opportunities from the fit-and-forget trend?
-
Toolbox of 6G Communications WIET, WET, next energy harvesting, biofuelcells, supercapacitors?
-
Where will they be combined and why the pivot to triboelectrics, multimode flexible etc.?
-
How, when for battery-free implants, continuous glucose monitors, smartwatches, cellphones, IoT?
-
Technology, standards and adoption roadmaps 2021-2041?
-
Market sizes 2021-2041?
-
What does the research pipeline tell us?
The Executive Summary and Conclusions is a quick read for those in a hurry, giving 13 key conclusions with all the trends and possibilities compared and 34 examples including lessons of a pictured cellphone and IoT teardown. See best harvesting technologies, 6G, supercapacitor and device roadmaps 2021-2041. The 40 forecasts of Chapter 2 are mostly calculated by IDTechEx. The Introduction consolidates needs, trends, options, methodology (6 routes), new focus and new toolbox to batteryless with nine examples. Consideration ranges from LPWAN to virus-destroying electrostatic facemasks and Samsung smartphone styluses.
The deep dive then begins with a chapter on Healthcare and Wearables - 20 packed pages including 20 examples, four routes to battery-free embedded heart assistance, triboelectric and biofuelcell breakthroughs, future. Learn why harvesting lower frequency "infrasound" is better than vibration harvesting for all wearables. Chapter 5 is IoT, SRWN such as Bluetooth, LPWAN battery elimination, 22 pages of comparisons, examples, predictions, possibilities. IoT is seriously assessed, distinguishing cynical renaming of existing things from genuinely new business that will be enabled by battery elimination.
Chapter 6 covers 6G Communications' promised Wireless Information and Energy Transfer WIET eliminating batteries. It has 12 packed pages of new infograms, tables, pictures. See how 5G and 6G fit in, the appraisal again being critical not adulation. Chapter 7 assesses the six routes to batteryless cellphones and wearables with such things as six harvesting cost projections, device power projections, combinational options, WET, the University of Washington battery-free cellphone and HD video streaming in seven pages. Chapter 8, 11 pages, is battery elimination by Wireless Energy Transfer WET to RFID and NFC, a huge success already, and potentially one in Real Time Locating Systems RTLS, the new 6G Communications promising breakthrough.
Chapter 9 "Eliminating batteries from building controls" takes 22 pages to compare technologies and opportunities with many examples detailed and big names NEC, Toshiba, Yamaha, ABB, Siemens. Chapters 10 and 11 are exceptionally long and thorough examinations of the principal tools of battery elimination - energy harvesting and supercapacitors both experiencing radical change, new options and variants and improvement in 2020/2021. Only the IDTechEx report, ""Battery Elimination in Electronics: Market Impact IoT, 6G, Healthcare, Wearables 2021-2041" has this latest news and insight, essential in such a fast-moving subject.
ページTOPに戻る
Table of Contents
|
1. |
EXECUTIVE SUMMARY AND CONCLUSIONS |
|
1.1. |
Purpose of this report |
|
1.2. |
Top ten electronic devices by number |
|
1.3. |
Top ten electronic devices by power choices and issues |
|
1.4. |
Some reasons for eliminating small batteries by application |
|
1.5. |
Batteryless is a strong selling point |
|
1.6. |
Thirteen key conclusions |
|
1.7. |
Energy harvesting options to power electronic and small electric devices |
|
1.8. |
Promising future applications by preferred energy harvesting technology - examples |
|
1.9. |
Example of battery issues: |
|
1.10. |
LPWAN/ IOT node teardown and battery elimination |
|
1.10.1. |
Battery cost share |
|
1.10.2. |
IoT battery elimination example March 2021 |
|
1.11. |
Roadmap for electronic device harvesting 2021-2041 |
|
1.12. |
6G Communications roadmap to battery elimination 2021-2041 |
|
1.13. |
Supercapacitor and device roadmap of battery elimination in electronics 2021-2041 |
|
2. |
MARKET FORECASTS |
|
2.1. |
Wireless electronics and small electric devices without batteries by type 2021 and 2041 |
|
2.2. |
Wireless electronics and small electric devices without batteries % $billion by sector 2041 |
|
2.3. |
IoT LPWAN connections |
|
2.4. |
Bluetooth device forecasts |
|
2.5. |
RFID forecasts |
|
2.6. |
Energy harvesting for electronics battery and batteryless forecasts |
|
2.6.1. |
Summary and roadmap 2020-2040 |
|
2.6.2. |
Photovoltaic energy harvesting for electronics: units, unit price, market value 2020-2040 |
|
2.6.3. |
Thermoelectric energy harvesting transducers by application number, price, market value 2019-2030 |
|
2.6.4. |
Piezoelectric energy harvesting for electronics: number, price, market value 2020-2030 |
|
2.6.5. |
Triboelectric transducer and self-powered sensors 2020-2040 $ million |
|
2.6.6. |
Electrodynamic energy harvesting for electronics: number, price, market value 2020-2040 |
|
2.7. |
Forecast for pico products (flashlights, lanterns etc) battery and batteryless with integral harvesting |
|
2.8. |
Global supercapacitor market by application |
|
2.8.1. |
$ billion 2021-2041 with 10 top suppliers' sales |
|
2.8.2. |
Global supercapacitor value market by territory 2021-2041 |
|
2.8.3. |
Earliest major adopter of supercapacitor advances by territory/ application 2021-2041 |
|
2.8.4. |
Continuous glucose monitoring CGM in context $ million to 2029 |
|
2.9. |
6G smartphones and total cellphones 2021-2041 |
|
3. |
INTRODUCTION |
|
3.1. |
Overview |
|
3.2. |
Power needed by electronics and small electrical devices |
|
3.3. |
Battery problems and alternatives |
|
3.4. |
Drivers and facilitators of battery elimination |
|
3.4.1. |
How it becomes more necessary and easier |
|
3.4.2. |
Rapid improvement in alternatives and more of them |
|
3.4.3. |
How to improve, shrink and eliminate batteries |
|
3.4.4. |
Principles of batteryless operation |
|
3.4.5. |
Battery Eliminator Circuits BEC |
|
3.5. |
Energy harvesting for devices |
|
3.5.1. |
Some options compared |
|
3.5.2. |
Example of harvesting ambient RF |
|
3.5.3. |
Example of thermoelectric harvesting: KCF Technologies |
|
4. |
HEALTHCARE AND WEARABLES |
|
4.1. |
Overview |
|
4.2. |
Harvesting acoustic movement: infrasound not vibration |
|
4.2.1. |
More efficient electrodynamic harvesting with mechanical storage |
|
4.2.2. |
Kinetic energy harvesters without the need of a battery |
|
4.3. |
Batteryless implanted pacemaker examples |
|
4.3.1. |
Triboelectric motion harvesting |
|
4.3.2. |
Piezoelectric and triboelectric |
|
4.3.3. |
Electrodynamic |
|
4.3.4. |
RF powered |
|
4.4. |
Batteryless from both feet |
|
4.5. |
Near-field-enabled clothing sensors |
|
4.6. |
Battery-free patch monitoring by optical power transfer |
|
4.7. |
Perspiration-powered e-skin for multiplexed wireless sensing |
|
4.8. |
Batteryless e-textile bioenergy microgrid |
|
4.9. |
Smart bandage battery-free |
|
4.10. |
Two batteryless triboelectric facemasks activated by breathing |
|
4.11. |
Thermoelectric battery-free wearables |
|
4.12. |
Wind-up foetal heart monitor |
|
4.13. |
Portal Instruments batteryless needle-free jet injection platform |
|
5. |
IOT, SRWN, LPWAN BATTERY ELIMINATION |
|
5.1. |
Overview |
|
5.2. |
The IoT problem |
|
5.3. |
Area wireless networks |
|
5.4. |
Cost challenge to sell billions yearly: what learning curves predict |
|
5.5. |
Trameto multimode battery-free IoT |
|
5.6. |
IoT node compromises assist |
|
5.7. |
Smaller, lighter photovoltaic IoT node |
|
5.8. |
Matrix thermoelectric power for IoT |
|
5.9. |
21 LPWAN silicon manufacturers - partners for IoT |
|
5.10. |
Smart metering |
|
5.11. |
RFID sensors |
|
5.12. |
Reality Checking the IOT story |
|
5.13. |
Industry 4.0 worldwide |
|
5.14. |
Cognitive buildings |
|
6. |
6G COMMUNICATIONS WIET ELIMINATING BATTERIES |
|
6.1. |
Overview |
|
6.2. |
Parasitic power from human RF emissions |
|
6.3. |
Cards, wireless sensors and RFID parasitically powered from 5G |
|
6.4. |
6G communications reducing and eliminating batteries |
|
6.4.1. |
Overview |
|
6.4.2. |
6G wireless information and energy transfer WIET |
|
6.4.3. |
6G progress |
|
6.4.4. |
The case against 6G |
|
6.4.5. |
6G roadmap 2021-2041 |
|
7. |
SIX ROUTES TO BATTERYLESS CELLPHONES AND WEARABLES |
|
7.1. |
Routes to batteryless energy independent wearables 2031 |
|
7.2. |
Ressence Model 2 and Swatch |
|
7.3. |
Batteryless energy independent smartphones 2036 |
|
7.3.1. |
Overview of six routes |
|
7.3.2. |
Battery-free cellphone using ambient light or RF |
|
7.4. |
Towards Battery-Free HD Video Streaming |
|
8. |
BATTERY ELIMINATION BY WET TO RFID, NFC, RTLS |
|
8.1. |
ページTOPに戻る
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Global IoT in Education Market Size study, by Offering (Hardware, Software, Service) by Application (Learning Management System, Classroom Management, Administration Management, Others) by End-User (K-12, Higher Education, Corporate) and Regional Forecasts 2022-2032
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IoTセンサー市場:製品タイプ、エンドユーザー、地域別(北米、欧州、アジア太平洋地域、中南米、中東・アフリカ):世界の産業分析、規模、シェア、成長、動向、予測、2024-2033年
よくあるご質問
IDTechEx社はどのような調査会社ですか?
IDTechExはセンサ技術や3D印刷、電気自動車などの先端技術・材料市場を対象に広範かつ詳細な調査を行っています。データリソースはIDTechExの調査レポートおよび委託調査(個別調査)を取り扱う日... もっと見る
調査レポートの納品までの日数はどの程度ですか?
在庫のあるものは速納となりますが、平均的には 3-4日と見て下さい。
但し、一部の調査レポートでは、発注を受けた段階で内容更新をして納品をする場合もあります。
発注をする前のお問合せをお願いします。
注文の手続きはどのようになっていますか?
1)お客様からの御問い合わせをいただきます。
2)見積書やサンプルの提示をいたします。
3)お客様指定、もしくは弊社の発注書をメール添付にて発送してください。
4)データリソース社からレポート発行元の調査会社へ納品手配します。
5) 調査会社からお客様へ納品されます。最近は、pdfにてのメール納品が大半です。
お支払方法の方法はどのようになっていますか?
納品と同時にデータリソース社よりお客様へ請求書(必要に応じて納品書も)を発送いたします。
お客様よりデータリソース社へ(通常は円払い)の御振り込みをお願いします。
請求書は、納品日の日付で発行しますので、翌月最終営業日までの当社指定口座への振込みをお願いします。振込み手数料は御社負担にてお願いします。
お客様の御支払い条件が60日以上の場合は御相談ください。
尚、初めてのお取引先や個人の場合、前払いをお願いすることもあります。ご了承のほど、お願いします。
データリソース社はどのような会社ですか?
当社は、世界各国の主要調査会社・レポート出版社と提携し、世界各国の市場調査レポートや技術動向レポートなどを日本国内の企業・公官庁及び教育研究機関に提供しております。
世界各国の「市場・技術・法規制などの」実情を調査・収集される時には、データリソース社にご相談ください。
お客様の御要望にあったデータや情報を抽出する為のレポート紹介や調査のアドバイスも致します。
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