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市場調查報告書

智慧型包裝實用化:透過電子產品強化品牌印象

Smart Packaging Comes To Market: Brand Enhancement with Electronics 2014-2024

出版商 IDTechEx Ltd. 商品編碼 260725
出版日期 內容資訊 英文 286 Pages
商品交期: 最快1-2個工作天內
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智慧型包裝實用化:透過電子產品強化品牌印象 Smart Packaging Comes To Market: Brand Enhancement with Electronics 2014-2024
出版日期: 2014年03月01日 內容資訊: 英文 286 Pages
簡介

電子產品技術,已經利用在各種商品包裝上,甜酒的寶特瓶和可發聲比薩箱、帶有電荷的殺蟲劑噴霧式,記錄服用數量與服用時間的醫藥品容器、用戶方可變更的行動電話的配件等各種物品出現。實現像這樣的包裝的印刷電子產品技術可削減約一半成本。因此,許多知名品牌企業,藉由開發與紙同樣厚度的批量產品可使用的電子產品包裝,提高消費者的便利性,試圖領先其他競爭公司。今後10年間電子智慧型包裝市場規模預計將擴大至14億5000萬美元以上。

本報告提供電子產品技術所利用的智慧包裝設備的全球市場的需求趨勢分析,未來前景,智慧包裝普及的必要性因素和阻礙市場成長因素,各種包裝的實例,各種相關技術,主要企業各公司簡介,為您概述為以下內容。

第1章 摘要與結論

  • 資料的檢驗
  • 市場次級區分的融合
  • 市場擴大步調無法提升的理由
  • 市場成長促進因素
  • 新的零件獨創性設計
  • 新的技術、產業推動因素與洞察
  • 市場背景
  • 使用者調查迴響

第2章 介紹

  • 包裝種類
  • 加速進化原因
  • 基本的硬體平台重要性
  • 電子包裝實用化延遲的原因

第3章 智慧型包裝相關、使用者調查與迴響

  • 市場促進因素
  • 使用者見解:應用需求
  • 使用者見解:技術需求

第4章 電子產品包裝需求

  • 安全性
  • 安全防盜對策
  • 獨立性/製品差異化
  • 便利性
  • 追加機能的品牌強化
  • 宣傳效果讓銷售增加
  • 娛樂
  • 防止誤用
  • 廢棄時的環境面課題
  • 包裝內環境品質管理
  • 品質保証
  • 顧客迴響
  • 省略麻煩手續
  • 成本削減、效率化、自動資料收集

第5章 實用化技術

  • 凸版資訊的新印刷電子產品
  • 太陽能充電包
  • 智慧基板
  • 透明或無形的電子產品
  • 可捲曲的電子產品
  • 伸縮、可變形的電子產品
  • 食用電子產品
  • 使用了電子產品的藝術
  • 電子摺紙
  • 有交付機製作用的包裝
  • 電子投藥、消費者資訊

第6章 市場需要的基本硬體平台

  • 可顯示的標籤
  • 有聲音的標籤
  • 可錄音的標籤
  • 文本滾動的標籤
  • 計時器
  • 使用期限自動調整功能
  • 其他感測器電子產品
  • 動態彩色標籤
  • 藥和化妝品的投藥系統
  • 超低價格的印刷RFID/EAS(防偷竊)標籤

第7章 今後可實現的電子包裝技術

  • 接近實用化技術
  • T-Ink技術

第8章 電子產品包裝實例

  • 搭載人性化介面的電子產品包裝(全26件)
  • 未搭載人性化介面電子產品包裝(全12件)

第9章 電子產品包裝用電子零件

  • 傳統型零件課題
  • 印刷電子產品與可實現的印刷電子產品
  • 紙基板與塑膠基板、直接印刷包裝
  • 無機電晶體與記憶體
  • 有機電晶體與記憶體
  • 顯示
  • 包裝用能源採集技術
  • 電池
  • 透明電池與太陽光發電:日本電氣、早稻田大學、產業技術綜合研究所(AIST)
  • 製品化的其他重要彈性零件
  • 新種類零件:輕薄彈性製品

第10章 智慧型包裝相關NFC

  • NFC(近距離無線通訊)背景
  • 主要引進趨勢
  • 結論:包裝相關NFC

第11章 主要供應商與開發企業檔案(共32家)

第12章 市場預測

  • 印刷電子產品普及預測
  • 低價電子製品普及驚人的慢
  • 究極潛在市場
  • 電子包裝市場未來展望
  • 品牌強化的進步
  • 印刷電子產品市場
  • 小型設備電池市場
  • 印刷電子產品新設計規範的必要性
  • 價值鏈發達的不均衡

附錄1:專業用語

附錄2:IDTECHEX調查報告、諮詢服務

圖表

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目錄

"The global demand for electronic smart packaging will grow to over $1.45 billion in the next decade."

Electronics and electrics are already used in packaging, from winking rum bottles and talking pizza boxes to aerosols that emit electrically charged insecticide that chases the bug. Electronic medication packs record how much is taken and when and prompts the user. Reprogrammable phone decoration has arrived. But that is just a warm up. The key enabling technology - printed electronics - often used with other conventional electronics - can make new packaging and product features feasible. Consequently, many leading brand owners have recently put multidisciplinary teams onto the adoption of the new paper thin electronics on their high volume packaging. It will provide a host of consumer benefits and make competition look very tired indeed. This is mainly about modern merchandising - progressing way beyond static print - and dramatically better consumer propositions.

Consumer goods market for e-packaging devices in millions of units*

*For the full forecast data please purchase this report
Source: IDTechEx

This report reveals the global demand for electronic smart packaging devices is currently at a tipping point and will grow rapidly to $1.45 billion within 10 years. The electronic packaging (e-packaging) market will remain primarily in consumer packaged goods (CPG) reaching 14.5 billion units that have electronic functionality within a decade.

E-packaging addresses the need for brands to reconnect with the customer or face oblivion from copying. That even applies to retailer own brands. It addresses the ageing population's consequent need for disposable medical testers and drug delivery devices. Electronic packaging addresses the fact that one third of us have difficulty reading ever smaller instructions.

Main drivers of the rapid growth

The rapid growth will be driven by trials now being carried out by leading CPG companies and the rapid technical developments emanating for over 3000 organisations, half of them academic, that are currently working on printed and potentially printed electronics.

The six main factors driving the rapid growth of electronic smart packaging are:

  • Ageing population
  • Consumers are more demanding
  • Consumers are more wealthy
  • Changing lifestyles
  • Tougher legislation
  • Concern about crime and the new terrorism

There will also be growth from existing applications such as talking pizza boxes, winking logos on multipacks of biscuits and bottles of rum, compliance monitoring blisterpacks in drug trials, prompting plastic bottles of drugs that prompt the user, testers on batteries and reprogrammable decoration on mobile phones. However, IDTechEx's projected adoption only represents a few percent of CPG packages being fitted with these devices in 2024.

There are still many challenges to be addressed, including creating sustainable e-packaging products rather than one-off projects. Cost and lack of integrators and complete product designers are current limitations.

All of these trends, including detailed ten year forecasts, are covered in this IDTechEx report "Smart Packaging Comes To Market: Brand Enhancement with Electronics 2014-2024". The report reveals many ways in which brands can create a sharp increase in market share, customer satisfaction and profitability. It covers case studies of successes and failures and why.

To gain very high volume, and therefore lowest costs, by selling across all industries, basic hardware platforms such as the very low cost talking label must be developed. These are discussed. The detailed market forecasts, statistics for associated industries, pros and cons, technology choices and lessons of success and failure provide a lucid, compact analysis for the busy executive. There is much for both non-technical and technical readers.

Forecasts are given in terms of number of units and total market value for each of the following:

  • Winking and decal refers to labels that wink an image on and off and reprogrammable decoration on mobile phones etc
  • Scrolling and page turn refers to text and graphics accessed by scrolling or page turning
  • Audio and timer refers to voice, music or alert sounds including those produced by timers or sensors
  • Status refers to visible indication of status as with the tester on a battery case and an indication of how much is left in an aerosol can
  • Other CPG
  • EAS (electronic article surveillance)
  • RFID drugs, postal, retail cases
  • RFID retail primary packs/item level
  • The impact of NFC on packaging

Table of Contents

1. EXECUTIVE SUMMARY AND CONCLUSIONS

  • 1.1. Benchmarking validation of figures
  • 1.2. Market sub sectors merge
    • 1.2.1. EAS and RFID
    • 1.2.2. NFC in Smart Packaging
  • 1.3. Reasons for the slow start
    • 1.3.1. Unbalanced supply chain
    • 1.3.2. Many examples of e-packaging
    • 1.3.3. Little market pull
    • 1.3.4. Tipping point
    • 1.3.5. P&G and printed electronics
    • 1.3.6. Using more of the human senses and in a better way
    • 1.3.7. Reusable electronic packaging
    • 1.3.8. Major adoption is certain now
    • 1.3.9. The forthcoming e-Label
    • 1.3.10. Technology push
  • 1.4. Market drivers
    • 1.4.1. Two routes for e-packaging
    • 1.4.2. Price sensitivity
    • 1.4.3. Basic hardware platforms are essential to achieve volume
  • 1.5. New components and creative design
    • 1.5.1. New design paradigms
    • 1.5.2. Electronic graphic design
    • 1.5.3. Diageo needs
  • 1.6. Emerging Technologies, Business Drivers and Insights
    • 1.6.1. Displays
    • 1.6.2. Power
    • 1.6.3. Other components: Logic, sensors, conductive ink
  • 1.7. Market Background
  • 1.8. Feedback from Interviews with End Users

2. INTRODUCTION

  • 2.1. Types of packaging
    • 2.1.1. Demographic timebomb
  • 2.2. Why progress is now much faster
    • 2.2.1. Using the nine human senses
    • 2.2.2. AstraZeneca Diprivan chipless RFID
  • 2.3. Why basic hardware platforms are essential
    • 2.3.1. Argument for printing standard circuits
    • 2.3.2. Touch and hearing
    • 2.3.3. Smell
  • 2.4. Why e-packaging has been slow to appear
    • 2.4.1. Inadequate market research
    • 2.4.2. Lack of market pull
    • 2.4.3. Wrong priorities by developers - engineering led design
    • 2.4.4. Inadequate cost reduction
    • 2.4.5. Odd inventions not economy of scale/hardware platforms
    • 2.4.6. Failure to solve technical problems
    • 2.4.7. Legal constraints
    • 2.4.8. Lessons from brand enhancement of cars using printed electronics

3. END USER INTERVIEWS AND FEEDBACK ON SMART PACKAGING

  • 3.1. Drivers
  • 3.2. End User Views - Application Needs
  • 3.3. End User Views - Technical Needs

4. THE NEED FOR ELECTRONICS IN PACKAGING

  • 4.1. Safety
  • 4.2. Security and reducing crime
  • 4.3. Uniqueness/ product differentiation
  • 4.4. Convenience
  • 4.5. Leveraging the brand with extra functions, brand enhancement
  • 4.6. Merchandising and increasing sales
    • 4.6.1. Attracting attention
    • 4.6.2. Rewards
  • 4.7. Entertainment
    • 4.7.1. Touchcode
  • 4.8. Error Prevention
  • 4.9. Environmental aspects of disposal
  • 4.10. Environmental quality control within the package
  • 4.11. Quality Assurance
  • 4.12. Consumer feedback
  • 4.13. Removing tedious procedures
  • 4.14. Cost reduction, efficiency and automated data collection

5. THE MAGIC THAT IS BECOMING POSSIBLE

  • 5.1. Printed electronics products from Toppan Forms
  • 5.2. Solar bags
  • 5.3. Smart substrates
  • 5.4. Transparent and invisible electronics
  • 5.5. Tightly rollable electronics
    • 5.5.1. Fault tolerant electronics
  • 5.6. Stretchable and morphing electronics
  • 5.7. Edible electronics
  • 5.8. Electronics as art
  • 5.9. Origami electronics
  • 5.10. The package becomes the delivery mechanism
  • 5.11. Electronic release, dispensing and consumer information

6. BASIC HARDWARE PLATFORMS NEEDED BY THE MARKET

  • 6.1. Winking image label
  • 6.2. Talking label
  • 6.3. Recording talking label
  • 6.4. Scrolling text label
  • 6.5. Timer
  • 6.6. Self adjusting use by date
  • 6.7. Other sensing electronics
  • 6.8. Moving color picture label
  • 6.9. Drug and cosmetic delivery system
  • 6.10. Ultra low cost printed RFID/EAS label

7. PRECURSORS OF IMPENDING E-PACKAGING CAPABILITIES

  • 7.1. Coming down market
  • 7.2. T-Ink and all the senses

8. EXAMPLES OF E-PACKAGING

  • 8.1. Examples of e-packaging and related uses with human interface
    • 8.1.1. Bombay Sapphire pack
    • 8.1.2. Printed electronics magazine cover - Blue Spark, NTERA, CalPoly, SiCal, Canvas and Ricoh
    • 8.1.3. Printed electronic greeting cards - Tigerprint, PragmatIC, and Novalia
    • 8.1.4. Cigarettes scrolling display - Kent
    • 8.1.5. Talking pill compliance kit - MeadWestvaco
    • 8.1.6. Monochrome reprogrammable phone decoration - Hitachi
    • 8.1.7. Color reprogrammable phone decoration - Hewlett Packard and Kent Display
    • 8.1.8. Rum winking segments - Coyopa
    • 8.1.9. Talking pizza boxes - National Football League and Mangia Media
    • 8.1.10. Batteries with integral battery tester - Duracell
    • 8.1.11. Point of Sale Material - News Corporation and T-Ink
    • 8.1.12. Place mats - McDonalds
    • 8.1.13. Animation and sound - Westpoint Stevens
    • 8.1.14. Board games become animated - Hasbro and Character Visions
    • 8.1.15. Interactive tablecloth - Hallmark
    • 8.1.16. Compliance monitoring blisterpack - National Institutes of Health/Fisher Scientific
    • 8.1.17. Compliance monitoring blisterpack laminate - Novartis/Compliers Group/DCM
    • 8.1.18. Smart blisterpack dispenser - Bang & Olufsen Medicom
    • 8.1.19. Winking sign - ACREO
    • 8.1.20. Compliance monitoring plastic bottle - Aardex
    • 8.1.21. Talking medicine - CVS and other US pharmacies
    • 8.1.22. Talking prizes - Coca-Cola
    • 8.1.23. Beer package game - VTT Technology
    • 8.1.24. Electronic cosmetic pack - Procter and Gamble
    • 8.1.25. Cookie heater pack - T-Ink
    • 8.1.26. Sata Airlines - Ynvisible
  • 8.2. Examples of e-packaging without human interface
    • 8.2.1. Time temperature label - Findus Bioett
    • 8.2.2. Anti-theft - Wal-Mart/Tyco ADT
    • 8.2.3. Time temperature recorders - Healthcare shippers/KSW Microtec
    • 8.2.4. Fly seeking spray - Reckitt Benkiser
    • 8.2.5. RFID for tracking - Tesco & Metro/Alien Technology
    • 8.2.6. Blisterpack with electronic feedback buttons - Kuopio University Hospital
    • 8.2.7. Trizivir - AstraZeneca
    • 8.2.8. Oxycontin - Purdue Pharma
    • 8.2.9. Viagra - Pfizer
    • 8.2.10. Theft detection - Swedish Postal Service and Deutsche Post
    • 8.2.11. Blood - Massachusetts General Hospital
    • 8.2.12. Real time locating systems - Jackson Healthcare Hospitals/Awarepoint

9. THE TOOLKIT OF ELECTRONIC COMPONENTS FOR E-PACKAGING

  • 9.1. Challenges of traditional components
  • 9.2. Printed and potentially printed electronics
    • 9.2.1. Successes so far
    • 9.2.2. Materials employed
    • 9.2.3. Printing technology employed
    • 9.2.4. Multiple film then components printed on top of each other
  • 9.3. Paper vs plastic substrates vs direct printing onto packaging
    • 9.3.1. Paper vs plastic substrates
    • 9.3.2. Electronic displays that can be printed on any surface
  • 9.4. Transistors and memory inorganic
    • 9.4.1. Nanosilicon ink
    • 9.4.2. Zinc oxide based ink
  • 9.5. Transistors and memory organic
  • 9.6. Displays
    • 9.6.1. Electrophoretic
    • 9.6.2. Thermochromic
    • 9.6.3. Electrochromic
    • 9.6.4. Printed LCD
    • 9.6.5. OLED
    • 9.6.6. Electrowetting
  • 9.7. Energy harvesting for packaging
    • 9.7.1. Photovoltaics
    • 9.7.2. Other
  • 9.8. Batteries
    • 9.8.1. Single use laminar batteries
    • 9.8.2. Rechargeable laminar batteries
    • 9.8.3. New shapes - laminar and flexible batteries
  • 9.9. Transparent batteries and photovoltaics - NEC, Waseda University, AIST
  • 9.10. Other important flexible components now available
    • 9.10.1. Capacitors and supercapacitors
    • 9.10.2. Applications for supercapacitors
    • 9.10.3. Resistors
    • 9.10.4. Conductive patterns for antennas, identification, keyboards etc.
    • 9.10.5. Programming at manufacturer, purchaser or end user
  • 9.11. New types of component - thin and flexible
    • 9.11.1. Memristors
    • 9.11.2. Metamaterials
    • 9.11.3. Thin film lasers, supercabatteries, fuel cells

10. NFC IN SMART PACKAGING

  • 10.1. NFC background
    • 10.1.1. 2010 Turning Point
    • 10.1.2. The biggest but least used RFID network today
    • 10.1.3. Beyond payments and transit
  • 10.2. Key adoption factors
    • 10.2.1. Technologies to address challenges
  • 10.3. Conclusions: NFC in Packaging

11. SUPPLIER AND DEVELOPER PROFILES

  • 11.1. ACREO, Sweden
  • 11.2. BASF, Germany
  • 11.3. Blue Spark Technologies, USA
  • 11.4. Canatu, Finland
  • 11.5. CapXX, Australia
  • 11.6. Cymbet, USA
  • 11.7. E-Ink
  • 11.8. Enfucell, Finland
  • 11.9. Excellatron, USA
  • 11.10. Fraunhofer Institute for Electronic Nano Systems (ENAS), Germany
  • 11.11. Front Edge Technology, USA
  • 11.12. Holst Centre, Netherlands
  • 11.13. Infinite Power Solutions USA
  • 11.14. Infratab, USA
  • 11.15. Institute of Bioengineering and Nanotechnology (A*Star), Singapore
  • 11.16. ISORG, France
  • 11.17. Kovio, USA
  • 11.18. Massachusetts Institute of Technology USA
  • 11.19. MWV, USA
  • 11.20. NEC, Japan
  • 11.21. New University of Lisbon, Portugal
  • 11.22. Novalia, UK
  • 11.23. Plastic Logic, UK
  • 11.24. PolyIC, Germany
  • 11.25. PragmatIC Printing, UK
  • 11.26. Printechnologics, Germany
  • 11.27. PST Sensor, South Africa
  • 11.28. Solarmer, USA
  • 11.29. Soligie, USA
  • 11.30. Thin Film Electronics, Norway
  • 11.31. T-Ink
  • 11.32. VTT, Finland

12. MARKET FORECASTS 2014-2024

  • 12.1. How printed electronics is being applied
  • 12.2. Surprisingly poor progress with low cost electronics so far
  • 12.3. Ultimate market potential
  • 12.4. E-packaging market 2014-2024
  • 12.5. Beyond brand enhancement
  • 12.6. Printed electronics market
  • 12.7. Battery market for small devices
  • 12.8. Printed electronics needs new design rules
  • 12.9. The emerging value chain is unbalanced

APPENDIX 1: GLOSSARY

APPENDIX 2: IDTECHEX PUBLICATIONS AND CONSULTANCY

TABLES

  • 1.1. Total market for e-packaging devices 2014-2024 in millions of units, unit value and total value
  • 1.2. Consumer goods market for e-packaging 2014-2024, in millions of units
  • 1.3. Global market for electronic smart packaging based on EAS or RFID in millions of units 2014-2024
  • 1.4. Potential use of packages in exploiting and mimicking human senses
  • 1.5. Main factors driving the rapid growth of electronic smart packaging
  • 2.1. Potential use of packages in exploiting and mimicking human senses.
  • 8.1. Bioett first customers
  • 9.1. Advantages and disadvantages of some options for supplying electricity to small devices
  • 9.2. Comparison of flexible photovoltaics technologies suitable for brand enhancement
  • 9.3. Comparison of the three types of capacitor when storing one kilojoule of energy
  • 9.4. Examples of energy density figures for batteries, supercapacitors and other energy sources
  • 9.5. Where supercapacitors fit in
  • 11.2. T-Ink Key Metrics
  • 12.1. Consumer goods market for e-packaging 2014-2024, in millions of units
  • 12.2. Global market for electronic smart packaging based on EAS or RFID in millions of units 2014-2024
  • 12.3. Split of small device battery market in 2011 by type, giving number, unit value, total value

FIGURES

  • 1.1. Total market for e-packaging devices 2014-2024 in millions of units, unit value and total value
  • 1.2. Consumer goods market for e-packaging devices 2014-2024 in millions of units
  • 1.3. Global market for electronic smart packaging based on EAS and RFID in millions of units 2014-2024
  • 1.4. Unbalanced supply chain for printed electronics
  • 1.5. Ultimate Smart Packaging
  • 1.6. Toppan Forms Audio Paper
  • 1.7. T-Ink electronic graphic design elements - some examples.
  • 1.8. Diageo needs for printed electronics
  • 1.9. Global electrophoretic e-readers sales (in million units)
  • 1.10. Examples of printed electronics creating new products
  • 2.1. Dependent elderly as percentage of total population
  • 2.2. Objectives of the EC Sustainpack project
  • 2.3. Paper food package with printed touch sensor and animated display with sound playback produced under the Sustainpack project
  • 2.4. Diprivan® TCI tag construction
  • 2.5. Tagged syringe and Diprifusor™
  • 2.6. Learning from experience with the silicon chip
  • 2.7. How printed standard platforms will progress
  • 2.8. Progress towards labels with many components printed on top of each other to provide multiple functionality such as the detergent that has sound and a winking logo
  • 2.9. Interactive paper
  • 2.10. Touch-sensor pads and wiring printed in interactive paper
  • 2.11. Experimental set up and demonstration
  • 2.12. Pressure sensitive film used in smart blisterpack by Plastic Electronic
  • 2.13. Some successes with packaging electronics that does not employ transistors
  • 2.14. Fully printed passive RFID, HurraFussball card bottom right
  • 2.15. Talking/ recording circuit as used in pizza boxes and gift cards, including Hallmark
  • 2.16. Talking circuit as used in pizza boxes and gift cards
  • 2.17. Hybrid devices used in packages, where the use of non-printing processes, silicon chips and some conventional components limits their success due to price, weight and size
  • 2.18. Remotely powered displays that could be used in packaging but a fully printed construction for the power supply not just the display is desirable for high volume use
  • 2.19. Box of cereal with moving colour displays as envisaged in "Minority Report"
  • 2.20. T-Ink ceiling cluster as used in the Ford Fusion car update from 2012
  • 4.1. CDT arguments for printed OLEDs
  • 4.2. Interactive shelf-package concept
  • 4.3. Concept of a disposable pack that can project a moving colour image onto a wall
  • 4.4. Speaking pot noodle that detects the hot water being applied and then monitors temperature or time
  • 4.5. Toppan Forms smart shop
  • 4.6. Concept of a valuable packaging tearoff
  • 4.7. Touchcode application examples
  • 5.1. Card with no battery, the image being illuminated by RF power from an RFID reader
  • 5.2. Flashing flexible OLED display at point of purchase POP
  • 5.3. Light emitting business card with images that light up sequentially
  • 5.4. Solar powered photo stand
  • 5.5. Flat sheet type of charger that is flexible
  • 5.6. OLED posters powered by flexible photovoltaics
  • 5.7. Light emitting display with audio all powered by ambient light
  • 5.8. Poster with electrophoretic display counting down to the arrival date of Beaujolais Nouveau
  • 5.9. Poster combining flashing LED with Toppan Forms Audio PaperTM sound
  • 5.10. Battery charging brief case with organic flexible photovoltaic panel
  • 5.11. Neuber's solar bag
  • 5.12. Lamborghini solar bag
  • 5.13. Mascotte DSSC solar bag
  • 5.14. Odersun solar bag
  • 5.15. Transparent electronics - a new packaging paradigm
  • 5.16. Stretchable electronics developed at Cambridge University UK
  • 5.17. Stretchable mesh of transistors connected by elastic conductors that were made at the University of Tokyo
  • 5.18. Reshaped electronics developed at Cambridge University UK
  • 5.19. Origami electronics
  • 5.20. eFlow nebuliser as used by AstraZeneca - a candidate for cost reduction to the point where it is disposable and comes with the drug inside
  • 6.1. Ink in Motion
  • 6.2. Voice recording gift tag by Talking Tags
  • 6.3. Concept of a drug container that prompts
  • 6.4. Concept of a voice recording gift pack
  • 6.5. Manually activated disposable paper timer for packaging
  • 6.6. Concept of an electronic package that has a blinking display and various safety sensors
  • 6.7. Concept of packaging preventing a health risk
  • 6.8. Electronic printed pain relief patch electronically delivering painkiller
  • 7.1. Examples of electronic devices coming down market with packaging a next possibility
  • 8.1. Bombay Sapphire with an EL display
  • 8.2. Scrolling display on Kent cigarettes
  • 8.3. Reprogrammable electrophoretic decoration on Hitachi mobile phones only needs power when being changed
  • 8.4. Reprogrammable color display on phone
  • 8.5. Duracell batteries/Avery Dennison tester
  • 8.6. National Institutes of Health/Fisher Scientific compliance monitoring blisterpack for Azithromycin trials, made by Information Mediary
  • 8.7. Compliers Group/ DCM compliance monitoring blisterpack overlay with RFID
  • 8.8. Bang & Olufsen Medicom compliance monitoring dispenser
  • 8.9. Aardex electronic plastic bottle for drug tablets
  • 8.10. Pill bottle with smart label (printed prescription label not shown)
  • 8.11. ScripTalk speaker
  • 8.12. VTT Technology beer package game
  • 8.13. Electrostatic cosmetic spray
  • 8.14. The ionisation technology used for the application of the foundation
  • 8.15. Bioett biosensor TTR
  • 8.16. Electrostatic insect-seeking fly spray in use
  • 8.17. Can of insect-seeking fly spray
  • 8.18. Knockdown efficiency of SmartSeeker®
  • 8.19. Compliance monitoring blisterpack with electronic feedback
  • 8.20. Tamper recording postal package
  • 8.21. Paling Risk Scale for major transfusion hazards
  • 8.22. SHOT project: cumulative data 1996 to 2001
  • 8.23. Increasing errors within hospitals
  • 8.24. Safe transfusion: Processes not just product
  • 8.25. Automated warning generated when a possible mis-match of blood and patient occurs
  • 8.26. RFID on blood container, next to interrogator
  • 8.27. Blood labelled with RFID chip
  • 9.1. Evolution of printed electronics geometry
  • 9.2. Multilayer interconnect development at Holst Research Centre
  • 9.3. Categories of organic semiconductor with examples and a picture of a Plastic Logic printed organic transistor
  • 9.4. The principle behind E-Ink's technology
  • 9.5. Electrophoretic display on Esquire magazine October 2008
  • 9.6. Electrophoretic display on pricing label
  • 9.7. Electrophoretic display on key fob
  • 9.8. Shelf edge labels using electrophoretic displays
  • 9.9. Color electrophoretics by Fujitsu
  • 9.10. Game in secondary packaging by VTT Technology using thermochromic display
  • 9.11. ACREO PEDOT PSS electrochromic blue display with limited bistable capability. A different message appears when the reverse nine volts is applied
  • 9.12. Color LCD by photo alignment
  • 9.13. Photo alignment of LCD
  • 9.14. The HKUST optical rewriting
  • 9.15. Color printable flexible LCD
  • 9.16. Basic structure of an OLED
  • 9.17. Process flow in manufacture of OLEDs
  • 9.18. A Cambridge Display Technology colour OLED display
  • 9.19. Comparison of different printing techniques for OLED frontplanes, as evaluated by Seiko Epson
  • 9.20. Droplet driven electrowetting displays from adt, Germany
  • 9.21. Energy harvesting challenges
  • 9.22. Rapid progress in the capabilities of small electronic devices and their photovoltaic energy harvesting contrasted with more modest progress in improving the batteries they employ
  • 9.23. Power in use vs duty cycle for portable and mobile devices showing zones of use of single use vs rechargeable batteries
  • 9.24. Enfucell SoftBattery™
  • 9.25. Blue Spark laminar battery
  • 9.26. Blue Spark battery printing machine
  • 9.27. Volumetric energy density vs gravimetric energy density for rechargeable batteries
  • 9.28. Laminar lithium ion battery
  • 9.29. Typical active RFID tag showing the problematic coin cells
  • 9.30. Construction of a lithium rechargeable laminar battery
  • 9.31. Reel to reel construction of rechargeable laminar lithium batteries
  • 9.32. Infinite Power Solutions laminar lithium battery
  • 9.33. Ultra thin lithium rechargeable battery
  • 9.34. Construction of a thin-film battery
  • 9.35. Battery assisted passive RFID label with rechargeable thin film lithium battery recording time-temperature profile of food, blood etc in transit
  • 9.36. Flexible battery made of nanotube ink
  • 9.37. Transparent flexible photovoltaics
  • 9.38. Flexible battery that charges in one minute
  • 9.39. E-labels with capacitor and no battery
  • 9.40. Energy density vs power density for storage devices
  • 9.41. Laminar supercapacitor one millimeter thick
  • 9.42. Mobile phone modified to give much brighter flash thanks to supercapacitor outlined in red
  • 9.43. Flexographically printed carbon resistors with silver interconnects
  • 9.44. Actuator/ push button - two printed patterns folded together
  • 9.45. Screen printed interconnects and actuator connects
  • 9.46. Other printed conductor pattern demonstrators
  • 9.47. Printechnologics gaming card showing conductive pattern, and AirCode touch
  • 9.48. Copper ink particles
  • 9.49. Programmability of potential e-labels through the value chain
  • 9.50. Memristor
  • 9.51. Microwave metamaterial
  • 11.1. Distribution and primary focus of 3000 developers of printed and potentially printed electronics. Many are developing a variety of printed components, their machinery or their materials
  • 11.2. Paper roulette card with simulated spinning wheel for game
  • 11.3. ACREO development process
  • 11.4. ACREO Technology
  • 11.5. ACREO microphones
  • 11.6. ACREO sensors
  • 11.7. ACREO production
  • 11.8. ACREO focus on e-packaging
  • 11.9. Demonstrator organic transistor
  • 11.10. The Cymbet EnerChip™
  • 11.11. Thin-film solid-state batteries by Excellatron
  • 11.12. Ultra low cost printed battery
  • 11.13. NanoEnergy® powering a blue LED
  • 11.14. DSP= digital signal processing
  • 11.15. New time temperature recording label from Infratab
  • 12.1. How printed electronics is being applied to products
  • 12.2. Printed Electronics Applications
  • 12.3. Cost per square centimeter and functionality
  • 12.4. Consumer goods market for e-packaging devices 2014-2024 in millions of units
  • 12.5. Global market for electronic smart packaging based on EAS and RFID in millions of units 2014-2024
  • 12.6. Market for printed and potentially printed electronics in 2014
  • 12.7. The emerging value chain is unbalanced
  • 12.8. Those going to market first move right
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