The Global Market for Printed and Flexible Electronics 2024-2034

1              EXECUTIVE SUMMARY   78

• 1.1          The evolution of electronics        80
• 1.2          Markets for printed and flexible electronics          83
  • 1.2.1      Macro-trends    83
  • 1.2.2      Healthcare and wellness               84
  • 1.2.3      Automotive        86
  • 1.2.4      Buildings and construction           87
  • 1.2.5      Energy storage and harvesting   88
  • 1.2.6      E-Textiles            89
  • 1.2.7      Consumer electronics    90
  • 1.2.8      Smart packaging and logistics      91
• 1.3          The wearables revolution             92
• 1.4          The wearable tech market in 2023             96
• 1.5          Continuous monitoring  97
• 1.6          Market map for printed and flexible electronics 98
• 1.7          Wearable market leaders             99
• 1.8          What is printed/flexible electronics?       100
  • 1.8.1      Motivation for use           100
  • 1.8.2      From rigid to flexible and stretchable      101
    • 1.8.2.1   Stretchable electronics  102
    • 1.8.2.2   Stretchable electronics in wearables       103
    • 1.8.2.3   Stretchable electronics in Medical devices            104
    • 1.8.2.4   Stretchable electronics in sensors             104
    • 1.8.2.5   Stretchable electronics in energy harvesting        105
    • 1.8.2.6   Stretchable artificial skin               105
• 1.9          Role in the metaverse   106
• 1.10        Wearable electronics in the textiles industry        107
• 1.11        New conductive materials            109
• 1.12        Entertainment  112
• 1.13        Growth in flexible and stretchable electronics market      113
  • 1.13.1    Recent growth in Printed, flexible and hyrbid products    113
  • 1.13.2    Future growth   114
  • 1.13.3    Advanced materials as a market driver   114
  • 1.13.4    Growth in remote health monitoring and diagnostics       115
• 1.14        Innovations at CES 2021-2024      117
• 1.15        Investment funding and buy-outs 2019-2024        119
• 1.16        Flexible hybrid electronics (FHE) 124
• 1.17        Sustainability in flexible electronics          128
• 1.18        Global market revenues, 2018-2034         128
  • 1.18.1    Consumer electronics    129
  • 1.18.2    Medical & healthcare     129
  • 1.18.3    E-textiles and smart apparel        130
  • 1.18.4    Displays                131
  • 1.18.5    Automotive        132
  • 1.18.6    Smart buildings 133
  • 1.18.7    Smart packaging               135

2              MANUFACTURING METHODS     136

• 2.1          Comparative analysis      136
• 2.2          Printed electronics          137
  • 2.2.1      Technology description 137
  • 2.2.2      SWOT analysis   138
• 2.3          3D electronics   139
  • 2.3.1      Technology description 139
  • 2.3.2      SWOT analysis   142
• 2.4          Analogue printing            143
  • 2.4.1      Technology description 143
  • 2.4.2      SWOT analysis   145
• 2.5          Digital printing   146
  • 2.5.1      Technology description 146
  • 2.5.2      SWOT analysis   148
• 2.6          In-mold electronics (IME)             149
  • 2.6.1      Technology description 149
  • 2.6.2      SWOT analysis   152
• 2.7          Roll-to-roll (R2R)               153
  • 2.7.1      Technology description 153
  • 2.7.2      SWOT analysis   156

3              MATERIALS AND COMPONENTS 158

• 3.1          Component attachment materials            158
  • 3.1.1      Conductive adhesives    160
  • 3.1.2      Biodegradable adhesives              160
  • 3.1.3      Magnets              160
  • 3.1.4      Bio-based solders            161
  • 3.1.5      Bio-derived solders         161
  • 3.1.6      Recycled plastics               161
  • 3.1.7      Nano adhesives 161
  • 3.1.8      Shape memory polymers              162
  • 3.1.9      Photo-reversible polymers          163
  • 3.1.10    Conductive biopolymers               164
  • 3.1.11    Traditional thermal processing methods 165
  • 3.1.12    Low temperature solder               165
  • 3.1.13    Reflow soldering              168
  • 3.1.14    Induction soldering         169
  • 3.1.15    UV curing             170
  • 3.1.16    Near-infrared (NIR) radiation curing         170
  • 3.1.17    Photonic sintering/curing             171
  • 3.1.18    Hybrid integration           171
• 3.2          Conductive inks 172
  • 3.2.1      Metal-based conductive inks      175
  • 3.2.2      Nanoparticle inks             176
  • 3.2.3      Silver inks            176
  • 3.2.4      Particle-Free conductive ink        178
  • 3.2.5      Copper inks        178
  • 3.2.6      Gold (Au) ink      180
  • 3.2.7      Conductive polymer inks               180
  • 3.2.8      Liquid metals     181
• 3.3          Printable semiconductors            183
  • 3.3.1      Technology overview     183
  • 3.3.2      Advantages and disadvantages  183
  • 3.3.3      SWOT analysis   185
• 3.4          Printable sensing materials          186
  • 3.4.1      Overview            186
  • 3.4.2      Types    186
  • 3.4.3      SWOT analysis   189
• 3.5          Flexible Substrates          190
  • 3.5.1      Flexible plastic substrates            192
    • 3.5.1.1   Types of materials            193
    • 3.5.1.2   Flexible (bio) polyimide PCBs      194
  • 3.5.2      Paper substrates              195
    • 3.5.2.1   Overview            195
  • 3.5.3      Glass substrates               196
    • 3.5.3.1   Overview            196
  • 3.5.4      Textile substrates            197
• 3.6          Flexible ICs          197
  • 3.6.1      Description         197
  • 3.6.2      Flexible metal oxide ICs 198
  • 3.6.3      Comparison of flexible integrated circuit technologies     199
  • 3.6.4      SWOT analysis   200
• 3.7          Printed PCBs      201
  • 3.7.1      Description         201
  • 3.7.2      High-Speed PCBs              203
  • 3.7.3      Flexible PCBs      204
  • 3.7.4      3D Printed PCBs                205
  • 3.7.5      Sustainable PCBs              206
• 3.8          Thin film batteries           206
  • 3.8.1      Technology description 206
  • 3.8.2      SWOT analysis   207
• 3.9          Energy harvesting            209
  • 3.9.1      Approaches        209
  • 3.9.2      Perovskite photovoltaics              209
  • 3.9.3      Applications       210
  • 3.9.4      SWOT analysis   211

4              PRINTED AND FLEXIBLE CONSUMER ELECTRONICS            212

• 4.1          Macro-trends    212
• 4.2          Market drivers  212
• 4.3          SWOT analysis   216
• 4.4          Wearable sensors            217
• 4.5          Wearable actuators         218
• 4.6          Recent market developments    219
• 4.7          Wrist-worn wearables   220
  • 4.7.1      Overview            220
  • 4.7.2      Sports-watches, smart-watches and fitness trackers         220
    • 4.7.2.1   Sensing   220
    • 4.7.2.2   Actuating             221
  • 4.7.3      SWOT analysis   225
  • 4.7.4      Health monitoring           226
  • 4.7.5      Energy harvesting for powering smartwatches    227
  • 4.7.6      Main producers and products     228
• 4.8          Sports and fitness            230
  • 4.8.1      Overview            230
  • 4.8.2      Wearable devices and apparel    230
  • 4.8.3      Skin patches       230
  • 4.8.4      Products              232
• 4.9          Hearables            234
  • 4.9.1      Technology overview     234
  • 4.9.2      Assistive Hearables         237
    • 4.9.2.1   Biometric Monitoring     237
  • 4.9.3      SWOT analysis   239
  • 4.9.4      Health & Fitness Hearables          240
  • 4.9.5      Multimedia Hearables   240
  • 4.9.6      Artificial Intelligence (AI)              240
  • 4.9.7      Companies and products              241
• 4.10        Sleep trackers and wearable monitors    242
  • 4.10.1    Built in function in smart watches and fitness trackers     243
  • 4.10.2    Smart rings         244
  • 4.10.3    Headbands         245
  • 4.10.4    Sleep monitoring devices             245
    • 4.10.4.1                Companies and products              246
• 4.11        Pet and animal wearables            247
• 4.12        Military wearables          248
• 4.13        Industrial and workplace monitoring       249
  • 4.13.1    Products              250
• 4.14        Global market revenues 252
• 4.15        Market challenges           253

5              PRINTED AND FLEXIBLE MEDICAL AND HEALTHCARE/WELLNESS ELECTRONICS      255

• 5.1          Macro-trends    255
• 5.2          Market drivers  255
• 5.3          SWOT analysis   258
• 5.4          Current state of the art  259
  • 5.4.1      Electrochemical biosensors         261
  • 5.4.2      Skin patches for continuous monitoring 261
  • 5.4.3      Printed pH sensors          262
  • 5.4.4      Wearable medical device products           262
  • 5.4.5      Temperature and respiratory rate monitoring     265
• 5.5          Wearable and health monitoring and rehabilitation          266
  • 5.5.1      Market overview             266
  • 5.5.2      Companies and products              267
• 5.6          Electronic skin patches  272
  • 5.6.1      Electronic skin sensors   273
  • 5.6.2      Conductive hydrogels for soft and flexible electronics      274
  • 5.6.3      Nanomaterials-based devices     276
    • 5.6.3.1   Graphene           277
  • 5.6.4      Liquid metal alloys           278
  • 5.6.5      Conductive hydrogels for soft and flexible electronics      278
  • 5.6.6      Printed batteries              279
  • 5.6.7      Materials             279
    • 5.6.7.1   Summary of advanced materials 280
  • 5.6.8      SWOT analysis   281
  • 5.6.9      Temperature and respiratory rate monitoring     282
    • 5.6.9.1   Market overview             282
    • 5.6.9.2   Companies and products              283
  • 5.6.10    Continuous glucose monitoring (CGM)   285
    • 5.6.10.1                Market overview             285
  • 5.6.11    Minimally-invasive CGM sensors               285
    • 5.6.11.1                Technologies     286
  • 5.6.12    Non-invasive CGM sensors          289
    • 5.6.12.1                Commercial devices        289
    • 5.6.12.2                Companies and products              290
  • 5.6.13    Cardiovascular monitoring           294
    • 5.6.13.1                Market overview             294
    • 5.6.13.2                ECG sensors       294
      • 5.6.13.2.1             Companies and products              295
    • 5.6.13.3                PPG sensors       297
      • 5.6.13.3.1             Companies and products              297
  • 5.6.14    Pregnancy and newborn monitoring        298
    • 5.6.14.1                Market overview             298
    • 5.6.14.2                Companies and products              298
  • 5.6.15    Hydration sensors           299
    • 5.6.15.1                Market overview             299
    • 5.6.15.2                Companies and products              300
  • 5.6.16    Wearable sweat sensors (medical and sports)     300
    • 5.6.16.1                Market overview             300
    • 5.6.16.2                Companies and products              303
• 5.7          Wearable drug delivery 304
  • 5.7.1      Companies and products              305
• 5.8          Cosmetics patches           306
  • 5.8.1      Companies and products              307
• 5.9          Femtech devices              308
  • 5.9.1      Companies and products              308
• 5.10        Smart footwear for health monitoring     310
  • 5.10.1    Companies and products              311
• 5.11        Smart contact lenses and smart glasses for visually impaired         311
  • 5.11.1    Companies and products              311
• 5.12        Smart woundcare            312
  • 5.12.1    Companies and products              314
• 5.13        Smart diapers    315
  • 5.13.1    Companies and products              315
• 5.14        Wearable robotics-exo-skeletons, bionic prostheses, exo-suits, and body worn collaborative robots           316
  • 5.14.1    Companies and products              317
• 5.15        Global market revenues 336
• 5.16        Market challenges           337

6              ELECTRONIC TEXTILES (E-TEXTILES) AND SMART APPAREL              339

• 6.1          Macro-trends    340
• 6.2          Market drivers  340
• 6.3          SWOT analysis   343
• 6.4          Performance requirements for E-textiles               344
• 6.5          Growth prospects for electronic textiles 345
• 6.6          Textiles in the Internet of Things               349
• 6.7          Types of E-Textile products          351
  • 6.7.1      Embedded e-textiles      352
  • 6.7.2      Laminated e-textiles       353
• 6.8          Materials and components          353
  • 6.8.1      Integrating electronics for E-Textiles        353
    • 6.8.1.1   Textile-adapted 355
    • 6.8.1.2   Textile-integrated           356
    • 6.8.1.3   Textile-based    356
  • 6.8.2      Manufacturing of E-textiles         356
    • 6.8.2.1   Integration of conductive polymers and inks        356
    • 6.8.2.2   Integration of conductive yarns and conductive filament fibers    359
    • 6.8.2.3   Integration of conductive sheets               360
  • 6.8.3      Flexible and stretchable electronics in E-textiles 360
  • 6.8.4      E-textiles materials and components       361
  • 6.8.4.1   Conductive and stretchable fibers and yarns        362
    • 6.8.4.1.1               Production          364
    • 6.8.4.1.2               Metals  365
    • 6.8.4.1.3               Carbon materials and nanofibers              366
      • 6.8.4.1.3.1           Graphene           369
      • 6.8.4.1.3.2           Carbon nanotubes           370
      • 6.8.4.1.3.3           Nanofibers         372
    • 6.8.4.2   Mxenes 374
    • 6.8.4.3   Hexagonal boron-nitride (h-BN)/Bboron nitride nanosheets (BNNSs)        375
    • 6.8.4.4   Conductive polymers     377
      • 6.8.4.4.1               PDMS    380
      • 6.8.4.4.2               PEDOT: PSS         380
      • 6.8.4.4.3               Polypyrrole (PPy)             380
      • 6.8.4.4.4               Conductive polymer composites 381
      • 6.8.4.4.5               Ionic conductive polymers           381
    • 6.8.4.5   Conductive inks 381
      • 6.8.4.5.1               Aqueous-Based Ink         384
      • 6.8.4.5.2               Solvent-Based Ink            385
      • 6.8.4.5.3               Oil-Based Ink      385
      • 6.8.4.5.4               Hot-Melt Ink      385
      • 6.8.4.5.5               UV-Curable Ink 386
      • 6.8.4.5.6               Metal-based conductive inks      387
        • 6.8.4.5.6.1           Nanoparticle ink               388
        • 6.8.4.5.6.2           Silver inks            388
        • 6.8.4.5.6.3           Copper inks        393
        • 6.8.4.5.6.4           Gold (Au) ink      395
      • 6.8.4.5.7               Carbon-based conductive inks    395
        • 6.8.4.5.7.1           Carbon nanotubes           395
        • 6.8.4.5.7.2           Single-walled carbon nanotubes 397
        • 6.8.4.5.7.3           Graphene           399
      • 6.8.4.5.8               Liquid metals     403
        • 6.8.4.5.8.1           Properties           403
    • 6.8.4.6   Electronic filaments        403
    • 6.8.4.7   Phase change materials 404
      • 6.8.4.7.1               Temperature controlled fabrics  404
    • 6.8.4.8   Shape memory materials              405
    • 6.8.4.9   Metal halide perovskites              407
    • 6.8.4.10                Nanocoatings in smart textiles   407
      • 6.8.4.11                3D printing          411
        • 6.8.4.11.1             Fused Deposition Modeling (FDM)           411
        • 6.8.4.11.2             Selective Laser Sintering (SLS)     411
        • 6.8.4.11.3             Products              411
  • 6.8.5      E-textiles components   413
    • 6.8.5.1   Sensors and actuators    413
      • 6.8.5.1.1               Physiological sensors      415
      • 6.8.5.1.2               Environmental sensors  415
      • 6.8.5.1.3               Pressure sensors              416
        • 6.8.5.1.3.1           Flexible capacitive sensors           416
        • 6.8.5.1.3.2           Flexible piezoresistive sensors   416
        • 6.8.5.1.3.3           Flexible piezoelectric sensors      417
      • 6.8.5.1.4               Activity sensors 417
      • 6.8.5.1.5               Strain sensors    417
        • 6.8.5.1.5.1           Resistive sensors              418
        • 6.8.5.1.5.2           Capacitive strain sensors              419
      • 6.8.5.1.6               Temperature sensors     419
      • 6.8.5.1.7               Inertial measurement units (IMUs)          419
    • 6.8.5.2   Electrodes           420
    • 6.8.5.3   Connectors         420
• 6.9          Applications, markets and products         420
  • 6.9.1      Current E-textiles and smart clothing products    421
  • 6.9.2      Temperature monitoring and regulation 423
    • 6.9.2.1   Heated clothing 423
    • 6.9.2.2   Heated gloves   424
    • 6.9.2.3   Heated insoles  425
    • 6.9.2.4   Heated jacket and clothing products        425
    • 6.9.2.5   Materials used in flexible heaters and applications            426
  • 6.9.3      Stretchable E-fabrics       427
  • 6.9.4      Therapeutic products     428
  • 6.9.5      Sport & fitness  429
    • 6.9.5.1   Products              431
  • 6.9.6      Smart footwear 433
    • 6.9.6.1   Companies and products              433
  • 6.9.7      Wearable displays            434
  • 6.9.8      Military 435
  • 6.9.9      Textile-based lighting     436
    • 6.9.9.1   OLEDs   436
  • 6.9.10    Smart gloves      437
  • 6.9.11    Powering E-textiles         437
    • 6.9.11.1                Advantages and disadvantages of main battery types for E-textiles            438
    • 6.9.11.2                Bio-batteries      439
    • 6.9.11.3                Challenges for battery integration in smart textiles           439
    • 6.9.11.4                Textile supercapacitors  441
    • 6.9.11.5                Energy harvesting            442
      • 6.9.11.5.1             Photovoltaic solar textiles            443
      • 6.9.11.5.2             Energy harvesting nanogenerators           445
        • 6.9.11.5.2.1         TENGs   446
        • 6.9.11.5.2.2         PENGs  446
    • 6.9.11.5.3             Radio frequency (RF) energy harvesting 446
  • 6.9.12    Motion capture for AR/VR            447
• 6.10        Global market revenues 449
• 6.11        Market challenges           451

7              PRINTED AND FLEXIBLE ENERGY STORAGE AND HARVESTING       453

• 7.1          Macro-trends    453
• 7.2          Market drivers  454
• 7.3          SWOT analysis   455
• 7.4          Applications of printed and flexible electronics   456
• 7.5          Flexible and stretchable batteries for electronics                456
• 7.6          Battery market megatrends        458
• 7.7          Solid-state thin film batteries      461
  • 7.7.1      Introduction       461
    • 7.7.1.1   Features and advantages              462
    • 7.7.1.2   Technical specifications 463
    • 7.7.1.3   Types    465
    • 7.7.1.4   Microbatteries  466
      • 7.7.1.4.1               Introduction       466
      • 7.7.1.4.2               Materials             467
        • 7.7.1.4.2.1           Applications       467
      • 7.7.1.4.3               3D designs          468
        • 7.7.1.4.3.1           3D printed batteries       468
    • 7.7.1.5   Bulk type solid-state batteries    469
    • 7.7.1.6   Shortcomings and market challenges for solid-state thin film batteries     469
• 7.8          Flexible batteries (including stretchable, rollable, bendable and foldable)               471
  • 7.8.1      Technical specifications 473
    • 7.8.1.1   Approaches to flexibility                474
      • 7.8.1.1.1               Flexible electronics          476
      • 7.8.1.1.2               Flexible materials             477
  • 7.8.2      Flexible and wearable Metal-sulfur batteries       478
  • 7.8.3      Flexible and wearable Metal-air batteries              479
  • 7.8.4      Flexible Lithium-ion Batteries     479
    • 7.8.4.1   Electrode designs             482
    • 7.8.4.2   Fiber-shaped Lithium-Ion batteries          485
    • 7.8.4.3   Stretchable lithium-ion batteries               486
    • 7.8.4.4   Origami and kirigami lithium-ion batteries            488
  • 7.8.5      Flexible Li/S batteries     489
    • 7.8.5.1   Components      490
    • 7.8.5.2   Carbon nanomaterials    490
  • 7.8.6      Flexible lithium-manganese dioxide (Li–MnO2) batteries 491
  • 7.8.7      Flexible zinc-based batteries       491
    • 7.8.7.1   Components      492
      • 7.8.7.1.1               Anodes 492
      • 7.8.7.1.2               Cathodes             493
    • 7.8.7.2   Challenges          493
    • 7.8.7.3   Flexible zinc-manganese dioxide (Zn–Mn) batteries          493
    • 7.8.7.4   Flexible silver–zinc (Ag–Zn) batteries       494
    • 7.8.7.5   Flexible Zn–Air batteries               495
    • 7.8.7.6   Flexible zinc-vanadium batteries               496
  • 7.8.8      Fiber-shaped batteries  497
    • 7.8.8.1   Carbon nanotubes           497
    • 7.8.8.2   Types    497
    • 7.8.8.3   Applications       499
    • 7.8.8.4   Challenges          499
  • 7.8.9      Transparent batteries    499
    • 7.8.9.1   Components      500
  • 7.8.10    Degradable batteries      502
    • 7.8.10.1                Components      502
  • 7.8.11    Flexible and stretchable supercapacitors               503
    • 7.8.11.1                Nanomaterials for electrodes     505
    • 7.8.11.2                Energy harvesting combined with wearable energy storage devices          507
• 7.9          Printed batteries              510
  • 7.9.1      Technical specifications 510
    • 7.9.1.1   Components      511
      • 7.9.1.1.1               Design  513
    • 7.9.1.2   Key features      514
    • 7.9.1.3   Printable current collectors          514
    • 7.9.1.4   Printable electrodes       515
    • 7.9.1.5   Materials             516
    • 7.9.1.6   Applications       517
    • 7.9.1.7   Printing techniques         518
    • 7.9.1.8   Applications       520
  • 7.9.2      Lithium-ion (LIB) printed batteries            520
  • 7.9.3      Zinc-based printed batteries       522
  • 7.9.4      3D Printed batteries       525
    • 7.9.4.1   3D Printing techniques for battery manufacturing             527
    • 7.9.4.2   Materials for 3D printed batteries            528
      • 7.9.4.2.1               Electrode materials         528
      • 7.9.4.2.2               Electrolyte Materials      529
  • 7.9.5      Printed supercapacitors 529
    • 7.9.5.1   Electrode materials         531
    • 7.9.5.2   Electrolytes        532
• 7.10        Photovoltaics     537
  • 7.10.1    Conductive pastes           537
  • 7.10.2    Organic photovoltaics (OPV)       538
  • 7.10.3    Perovskite PV    538
  • 7.10.4    Flexible and stretchable photovoltaics    539
    • 7.10.4.1                Companies         539
  • 7.10.5    Photovoltaic solar textiles            539
  • 7.10.6    Solar tape            541
  • 7.10.7    Origami-like solar cells   541
  • 7.10.8    Spray-on and stick-on perovskite photovoltaics  542
  • 7.10.9    Photovoltaic solar textiles            542
• 7.11        Stretchable heaters        544
• 7.12        Spray-on thermoelectric energy harvesting          545
• 7.13        Paper based fuel cells     545
• 7.14        Global market revenues 545
• 7.15        Market challenges           548

8              PRINTED AND FLEXIBLE DISPLAYS              549

• 8.1          Macro-trends    549
• 8.2          Market drivers  549
• 8.3          SWOT analysis   553
• 8.4          Printed and flexible display prototypes and products       554
• 8.5          Organic LCDs (OLCDs)    559
• 8.6          Flexible AMOLEDs            560
• 8.7          Flexible PMOLED (Passive Matrix OLED) 562
  • 8.7.1      Printed OLEDs    562
    • 8.7.1.1   Performance     563
    • 8.7.1.2   Challenges          563
    • 8.7.1.3   Commercial inkjet-printed OLED displays               563
• 8.8          Flexible and foldable microLED   564
  • 8.8.1      Foldable microLED displays          566
  • 8.8.2      Product developers        566
• 8.9          Flexible QD displays        568
• 8.10        Smartphones     569
• 8.11        Laptops, tablets and other displays           572
• 8.12        Products and prototypes              574
  • 8.13        Flexible lighting 580
    • 8.13.1    OLED lighting      580
    • 8.13.2    Automotive applications               581
      • 8.13.2.1                Commercial activity         582
• 8.14        FHE for large area lighting             582
• 8.15        Directly printed LED lighting         583
• 8.16        Flexible electrophoretic displays                584
  • 8.16.1    Commercial activity         585
• 8.17        Electrowetting displays  587
• 8.18        Electrochromic displays 588
• 8.19        Perovskite light-emitting diodes (PeLEDs)             589
  • 8.19.1    Types    589
  • 8.19.2    Challenges          590
  • 8.19.3    White PeLEDs    590
  • 8.19.4    Printable and flexible electronics               590
• 8.20        Metamaterials  591
  • 8.20.1    Metasurfaces    591
    • 8.20.1.1                Flexible metasurfaces    592
    • 8.20.1.2                Meta-Lens          593
    • 8.20.1.3                Metasurface holograms 594
    • 8.20.1.4                Stretchable displays        594
    • 8.20.1.5                Soft materials    595
• 8.21        Transparent displays       597
  • 8.21.1    Product developers        600
• 8.22        Global market revenues 601
• 8.23        Market challenges           603

9              PRINTED AND FLEXIBLE AUTOMOTIVE ELECTRONICS        604

• 9.1          Macro-trends    604
• 9.2          Market drivers  604
• 9.3          SWOT analysis   604
• 9.4          Applications       605
  • 9.4.1      Electric vehicles 606
    • 9.4.1.1   Applications       606
    • 9.4.1.2   Battery monitoring and heating 606
    • 9.4.1.3   Printed temperature sensors and heaters             607
  • 9.4.2      HMI       607
  • 9.4.3      Automotive displays and lighting               608
    • 9.4.3.1   Interiors               608
      • 9.4.3.1.1               OLED and flexible displays            610
      • 9.4.3.1.2               Passive-matrix OLEDs     611
      • 9.4.3.1.3               Active matrix OLED          612
      • 9.4.3.1.4               Transparent OLED for heads-up displays 612
      • 9.4.3.1.5               LCD displays       613
      • 9.4.3.1.6               Micro-LEDs in automotive displays           614
        • 9.4.3.1.6.1           Head-up display (HUD)  617
        • 9.4.3.1.6.2           Headlamps         618
        • 9.4.3.1.6.3           Product developers        619
    • 9.4.3.2   Exteriors              620
  • 9.4.4      In-Mold Electronics         621
  • 9.4.5      Printed and flexible sensors        622
    • 9.4.5.1   Capacitive sensors           622
    • 9.4.5.2   Flexible and stretchable pressure sensors             623
    • 9.4.5.3   Piezoresistive sensors    623
    • 9.4.5.4   Piezoelectric sensors      625
    • 9.4.5.5   Image sensors   627
      • 9.4.5.5.1               Materials and technologies         628
  • 9.4.6      Printed heaters 629
    • 9.4.6.1   Printed car seat heaters 630
    • 9.4.6.2   Printed/flexible interior heaters 631
    • 9.4.6.3   Printed on-glass heater 631
    • 9.4.6.4   Carbon nanotube transparent conductors             632
    • 9.4.6.5   Metal mesh transparent conductors        632
    • 9.4.6.6   3D shaped transparent heaters 632
    • 9.4.6.7   Direct heating    633
    • 9.4.6.8   Transparent heaters       634
  • 9.4.7      Transparent antennas    635
  • 9.4.8      Global market revenues 638
  • 9.4.9      Market challenges           639

10           PRINTED AND FLEXIBLE SMART BUILDINGS AND CONSTRUCTION ELECTRONICS   641

• 10.1        Macro-trends    641
• 10.2        Market drivers  641
• 10.3        SWOT analysis   643
• 10.4        Applications       644
  • 10.4.1    Industrial asset tracking/monitoring with hybrid electronics          645
  • 10.4.2    Customizable interiors   645
  • 10.4.3    Sensors 646
    • 10.4.3.1                Capacitive sensors           649
    • 10.4.3.2                Temperature and humidity sensors          649
    • 10.4.3.3                Sensors for air quality     651
    • 10.4.3.4                Magnetostrictive sensors             652
    • 10.4.3.5                Magneto- and electrorheological fluids   652
    • 10.4.3.6                CO2 sensors for energy efficient buildings             652
  • 10.4.4    Building integrated transparent antennas             654
  • 10.4.5    Reconfigurable intelligent surfaces (RIS) 655
  • 10.4.6    Industrial monitoring      656
• 10.5        Global market revenues 657

11           SMART PACKAGING ELECTRONICS            659

• 11.1        What is Smart Packaging?             659
  • 11.1.1    Flexible hybrid electronics (FHE) 661
  • 11.1.2    Printed batteries and antennas  663
  • 11.1.3    Flexible silicon integrated circuits              665
  • 11.1.4    Natural materials in packaging    666
  • 11.1.5    Extruded conductive pastes and inkjet printing   666
  • 11.1.6    OLEDs for smart and interactive packaging            667
  • 11.1.7    Active packaging               668
  • 11.1.8    Intelligent packaging       670
    • 11.1.8.1                Smart Cards        671
    • 11.1.8.2                RFID tags             671
      • 11.1.8.2.1             Low-frequency (LF) RFID tags: 30 KHz to 300 KHz                672
      • 11.1.8.2.2             High-frequency (HF) RFID tags: 3 to 30 MHz          672
      • 11.1.8.2.3             Ultra-high-frequency (UHF) RFID tags: 300 MHz to 3GHz 673
      • 11.1.8.2.4             Active, passive and semi-passive RFID tags            673
    • 11.1.8.3                Temperature Indicators 674
    • 11.1.8.4                Freshness Indicators       676
    • 11.1.8.5                Gas Indicators    677
• 11.2        SWOT analysis   678
• 11.3        Supply chain management          679
• 11.4        Improving product freshness and extending shelf life       680
• 11.5        Brand protection and anti-counterfeiting              681
• 11.6        Printed and flexible electronics in packaging        682
  • 11.6.1    FHE with printed batteries and antennas for smart packaging       683
  • 11.6.2    Printed codes and markings         684
  • 11.6.3    Barcodes (D)      684
  • 11.6.4    D data matrix codes        687
  • 11.6.5    Quick response (QR) codes          687
  • 11.6.6    Augmented reality (AR) codes    688
  • 11.6.7    Sensors and indicators   689
    • 11.6.7.1                Freshness Indicators       689
    • 11.6.7.2                Time-temperature indicator labels (TTIs)               690
    • 11.6.7.3                Natural colour formulation indicator        691
    • 11.6.7.4                Thermochromic inks       692
    • 11.6.7.5                Gas indicators    693
    • 11.6.7.6                Chemical Sensors             694
    • 11.6.7.7                Electrochemical-Based Sensors  694
    • 11.6.7.8                Optical-Based Sensors   695
    • 11.6.7.9                Biosensors          695
      • 11.6.7.9.1             Electrochemical-Based Biosensors            695
      • 11.6.7.9.2             Optical-Based Biosensors             696
    • 11.6.7.10              Edible Sensors   696
  • 11.6.8    Antennas            697
    • 11.6.8.1                Radio frequency identification (RFID)      697
      • 11.6.8.1.1             RFID technologies            698
        • 11.6.8.1.1.1         Biosensors on RFID tags 699
        • 11.6.8.1.1.2         Powerless RFID sensor tags          700
        • 11.6.8.1.1.3         RFID ICs with Large Area Printed Sensors               700
        • 11.6.8.1.1.4         RFID for anti-counterfeiting         701
      • 11.6.8.1.2             Passive RFID       703
      • 11.6.8.1.3             Active RFID         704
        • 11.6.8.1.3.1         Real Time Locating Systems (RTLS)           704
        • 11.6.8.1.3.2         Bluetooth Low Energy (BLE) and Low Power Wide Area Networks (LPWAN)           705
      • 11.6.8.1.4             Chipless RFID or Flexible/Printed IC Passive tags 705
      • 11.6.8.1.5             RAIN (UHF RFID) Smart Packaging             706
    • 11.6.8.2                Near-field communications (NFC)             706
  • 11.6.9    Smart blister packs          707
• 11.7        Global market revenues 709

12           COMPANY PROFILES       712 (690company profiles)

13           RESEARCH METHODOLOGY         1262

14           REFERENCES       1263

List of Tables

• Table 1. Macro-trends driving printed/flexible electronics.            83
• Table 2. Applications of printed and flexible electronics in healthcare & wellness.               84
• Table 3. Applications of printed and flexible electronics in automotive.    86
• Table 4. Applications of printed and flexible electronics in buildings and construction.      87
• Table 5. Applications of printed and flexible electronics in energy storage and harvesting.               88
• Table 6. Applications of printed and flexible electronics in E-textiles.        89
• Table 7. Applications of printed and flexible electronics in consumer electronics. 90
• Table 8. Applications of printed and flexible electronics in smart packaging and logistics.  91
• Table 9. Types of wearable devices and applications.        93
• Table 10. Types of wearable devices and the data collected.         95
• Table 11. Main Wearable Device Companies by Shipment Volume, Market Share, and Year-Over-Year Growth, (million units).   96
• Table 12. New wearable tech products 2022-2024.             96
• Table 13. Wearable market leaders by market segment. 99
• Table 14. Applications of stretchable electronics in wearables.    103
• Table 15. Applications of stretchable electronics in sensors.          104
• Table 16.  Applications of stretchable artificial skin electronics     105
• Table 17. Applications for printed flexible and stretchable electronics in the metaverse.  106
• Table 18. Advanced materials for Printed, flexible and stretchable sensors and Electronics-Advantages and disadvantages.  109
• Table 19. Sheet resistance (RS) and transparency (T) values for transparent conductive oxides and alternative materials for transparent conductive electrodes (TCE).   110
• Table 20. Applications of printed flexible and stretchable electronics in the entertainment industry.          112
• Table 21. Wearable, printed and flexible electronics at CES 2021-2024.     116
• Table 22. Wearables Investment funding and buy-outs 2019-2024.             119
• Table 23. Comparative analysis of conventional and flexible hybrid electronics.    124
• Table 24. Materials, components, and manufacturing methods for FHE    126
• Table 25. Research and commercial activity in FHE.           127
• Table 26. Manufacturing methods for printed, flexible and hybrid electronics.      137
• Table 27.  Common printing methods used in printed electronics manufacturing in terms of resolution vs throughput.                138
• Table 28. Manufacturing methods for 3D electronics.      140
• Table 29.  Readiness level of various additive manufacturing technologies for electronics applications.      141
• Table 30. Fully 3D printed electronics process steps          142
• Table 31. Manufacturing methods for Analogue manufacturing. 144
• Table 32. Technological and commercial readiness level of analogue printing methods.    146
• Table 33. Manufacturing methods for Digital printing       147
• Table 34. Innovations in high resolution printing.               148
• Table 35. Key manufacturing methods for creating smart surfaces with integrated electronics.      151
• Table 36. IME manufacturing techniques.             152
• Table 37. Applications of R2R electronics manufacturing.               155
• Table 38. Technology readiness level for R2R manufacturing.       157
• Table 39. Materials for printed and flexible electronics.  159
• Table 40. Comparison of component attachment materials.          159
• Table 41. Comparison between sustainable and conventional component attachment materials for printed circuit boards  160
• Table 42. Comparison between the SMAs and SMPs.       163
• Table 43. Comparison of conductive biopolymers versus conventional materials for printed circuit board fabrication.                165
• Table 44. Low temperature solder alloys.              166
• Table 45. Thermally sensitive substrate materials.             167
• Table 46. Typical conductive ink formulation.      173
• Table 47. Comparative properties of conductive inks.       176
• Table 48. Comparison of the electrical conductivities of liquid metal with typical conductive inks. 182
• Table 49. Conductive ink producers.        182
• Table 50. Technology readiness level of printed semiconductors. 184
• Table 51. Organic semiconductors: Advantages and disadvantages.           184
• Table 52. Market Drivers for printed/flexible sensors.      187
• Table 53. Overview of specific printed/flexible sensor types.        187
• Table 54. Properties of typical flexible substrates.             191
• Table 55. Comparison of stretchable substrates. 191
• Table 56.  Main types of materials used as flexible plastic substrates in flexible electronics.            194
• Table 57. Applications of flexible (bio) polyimide PCBs.    195
• Table 58. Paper substrates: Advantages and disadvantages.         196
• Table 59. Comparison of flexible integrated circuit technologies. 200
• Table 60. PCB manufacturing process.    203
• Table 61. Challenges in PCB manufacturing.         203
• Table 62. 3D PCB manufacturing.              206
• Table 63. Macro-trends in consumer electronics.               213
• Table 64. Market drivers and trends in wearable electronics.        214
• Table 65. Types of wearable sensors.      218
• Table 66. Trends in wearable technology.             219
• Table 67. Different sensing modalities that can be incorporated into wrist-worn wearable device.               221
• Table 68. Overview of actuating at the wrist         223
• Table 69. Wearable health monitors.       227
• Table 70. Sports-watches, smart-watches and fitness trackers producers and products.    229
• Table 71. Wearable sensors for sports performance.        232
• Table 72. Wearable sensor products for monitoring sport performance.  233
• Table 73.  Product types in the hearing assistance technology market.     237
• Table 74. Sensing options in the ear.        239
• Table 75. Companies and products in hearables. 242
• Table 76. Example wearable sleep tracker products and prices.    243
• Table 77. Smart ring products.    245
• Table 78. Sleep headband products.        246
• Table 79. Sleep monitoring products.      247
• Table 80. Pet wearable companies and products.               248
• Table 81. Wearable electronics applications in the military.           250
• Table 82. Wearable workplace products.               251
• Table 83. Global market revenues for printed and flexible in consumer electronics, 2018-2034, (millions USD).      254
• Table 84. Market challenges in consumer wearable electronics.  254
• Table 85. Macro trends in medical & healthcare/ wellness.           256
• Table 86. Market drivers for printed, flexible and stretchable medical and healthcare sensors and wearables.        257
• Table 87. Healthcare/wellness applications for printed/flexible electronics.           261
• Table 88. Examples of wearable medical device products.              264
• Table 89. Medical wearable companies applying products to remote monitoring and analysis.       266
• Table 90. Electronic skin patch manufacturing value chain.            274
• Table 91. Benefits of electronic skin patches as a form factor.       276
• Table 92. Current and emerging applications for electronic skin patches. 277
• Table 93. Applications in flexible and stretchable health monitors, by advanced materials type and benefits thereof.                281
• Table 94. Medical wearable companies applying products to temperate and respiratory monitoring and analysis. 285
• Table 95. Technologies for minimally-invasive and non-invasive glucose detection-advantages and disadvantages.                287
• Table 96. Commercial devices for non-invasive glucose monitoring not released or withdrawn from market.          290
• Table 97. Minimally-invasive and non-invasive glucose monitoring products.         291
• Table 98. Companies developing wearable swear sensors.             304
• Table 99. Wearable drug delivery companies and products.          306
• Table 100. Companies and products, cosmetics and drug delivery patches.            308
• Table 101. Companies developing femtech wearable technology.              309
• Table 102. Companies and products in smart footwear.  312
• Table 103. Companies and products in smart contact lenses.        312
• Table 104. Companies and products in smart wound care.             315
• Table 105. Companies developing smart diaper products.              316
• Table 106. Companies developing wearable robotics.      318
• Table 107. Global market for printed and flexible medical & healthcare electronics, 2018-2034, millions of US dollars.                337
• Table 108. Market challenges in medical and healthcare sensors and wearables. 338
• Table 109. Macro-trends for electronic textiles.  341
• Table 110. Market drivers for printed, flexible, stretchable and organic electronic textiles.              341
• Table 111. Examples of smart textile products.   343
• Table 112. Performance requirements for E-textiles.        345
• Table 113. Commercially available smart clothing products.          352
• Table 114. Types of smart textiles.           356
• Table 115. Comparison of E-textile fabrication methods. 357
• Table 116. Types of fabrics for the application of electronic textiles.          358
• Table 117. Methods for integrating conductive compounds.         359
• Table 118. Methods for integrating conductive yarn and conductive filament fiber.            360
• Table 119. 1D electronic fibers including the conductive materials, fabrication strategies, electrical conductivity, stretchability, and applications.  362
• Table 120. Conductive materials used in smart textiles, their electrical conductivity and percolation threshold.     366
• Table 121. Metal coated fibers and their mechanisms.    367
• Table 122. Applications of carbon nanomaterials and other nanomaterials in e-textiles.   368
• Table 123. Applications and benefits of graphene in textiles and apparel. 370
• Table 124. Properties of CNTs and comparable materials.               371
• Table 125. Properties of hexagonal boron nitride (h-BN). 377
• Table 126. Types of flexible conductive polymers, properties and applications.     379
• Table 127. Typical conductive ink formulation.    383
• Table 128. Comparative properties of conductive inks.    384
• Table 129.  Comparison of pros and cons of various types of conductive ink compositions.              387
• Table 130. Properties of CNTs and comparable materials.               397
• Table 131. Properties of graphene.          400
• Table 132. Electrical conductivity of different types of graphene. 403
• Table 133. Comparison of the electrical conductivities of liquid metal with typical conductive inks.              404
• Table 134. Nanocoatings applied in the smart textiles industry-type of coating, nanomaterials utilized, benefits and applications.       409
• Table 135. 3D printed shoes.      413
• Table 136. Sensors used in electronic textiles.     414
• Table 137. Features of flexible strain sensors with different structures.   419
• Table 138. Features of resistive and capacitive strain sensors.      420
• Table 139. Typical applications and markets for e-textiles.             421
• Table 140. Commercially available E-textiles and smart clothing products.              422
• Table 141. Example heated jacket products.         425
• Table 142. Heated jacket and clothing products. 426
• Table 143. Examples of materials used in flexible heaters and applications.            427
• Table 144. Commercialized smart textiles/or e-textiles for healthcare and fitness applications.      431
• Table 145. Example earable sensor products for monitoring sport performance. 432
• Table 146.Companies and products in smart footwear.   435
• Table 147. Wearable electronics applications in the military.         437
• Table 148. Advantages and disadvantages of batteries for E-textiles.         439
• Table 149. Comparison of prototype batteries (flexible, textile, and other) in terms of area-specific performance. 441
• Table 150. Advantages and disadvantages of photovoltaic, piezoelectric, triboelectric, and thermoelectric energy harvesting in of e-textiles.           443
• Table 151. Teslasuit.       450
• Table 152. Global market for printed and flexible E-textiles and smart apparel electronics, 2018-2034, millions of US dollars. 450
• Table 153. Market and technical challenges for E-textiles and smart clothing.        452
• Table 154. Macro-trends in printed and flexible electronics in energy.      454
• Table 155. Market drivers for Printed and flexible electronic energy storage, generation and harvesting.  455
• Table 156. Energy applications for printed/flexible electronics.   457
• Table 157. Battery market megatrends. 459
• Table 158. Market segmentation and status for solid-state batteries.        462
• Table 159. Shortcoming of solid-state thin film batteries.               470
• Table 160. Flexible battery applications and technical requirements.        473
• Table 161. Flexible Li-ion battery prototypes.      481
• Table 162. Electrode designs in flexible lithium-ion batteries.       483
• Table 163. Summary of fiber-shaped lithium-ion batteries.            486
• Table 164. Types of fiber-shaped batteries.          498
• Table 165. Components of transparent batteries.              501
• Table 166. Components of degradable batteries.               503
• Table 167. Applications of nanomaterials in flexible and stretchable supercapacitors, by advanced materials type and benefits thereof.              507
• Table 168. Main components and properties of different printed battery types.  513
• Table 169, Types of printable current collectors and the materials commonly used.           515
• Table 170. Applications of printed batteries and their physical and electrochemical requirements.              518
• Table 171. 2D and 3D printing techniques.            519
• Table 172. Printing techniques applied to printed batteries.          521
• Table 173. Main components and corresponding electrochemical values of lithium-ion printed batteries. 521
• Table 174. Printing technique, main components and corresponding electrochemical values of printed batteries based on Zn–MnO2 and other battery types.    523
• Table 175. Main 3D Printing techniques for battery manufacturing.           528
• Table 176. Electrode Materials for 3D Printed Batteries. 529
• Table 177. Methods for printing supercapacitors.              531
• Table 178. Electrode Materials for printed supercapacitors.          532
• Table 179. Electrolytes for printed supercapacitors.          534
• Table 180. Main properties and components of printed supercapacitors. 534
• Table 181. Conductive pastes for photovoltaics. 538
• Table 182. companies commercializing thin film flexible photovoltaics     540
• Table 183. Examples of materials used in flexible heaters and applications.            545
• Table 184. Global market for printed and flexible energy storage, generation and harvesting electronics, 2018-2034, millions of US dollars.     547
• Table 185. Market challenges in printed and flexible electronics for energy.          549
• Table 186. Macro-trends in displays.        550
• Table 187. Market drivers for Printed and flexible displays and electronic components.    550
• Table 188. Printed and flexible displays products.              555
• Table 189. Flexible miniLED and MicroLED products.        572
• Table 190. Comparison of performance metrics between microLEDs and other commercial display technologies. 572
• Table 191. Foldable smartphones, laptops and tablets and other display products, on or near market.       580
• Table 192. Companies developing OLED lighting products.             587
• Table 193. Types of electrochromic materials and applications.    594
• Table 194. Applications of Mini-LED and Micro-LED transparent displays. 603
• Table 195. Companies developing Micro-LED transparent displays.            606
• Table 196. Global market for printed and flexible displays, 2018-2034, millions of US dollars.         607
• Table 197. Market challenges in printed and flexible displays.      609
• Table 198.  Macro-trends in automotive.               610
• Table 199. Market drivers for printed and flexible electronics in automotive.        610
• Table 200. Printed and flexible electronics in the automotive market.       612
• Table 201. Printed/flexible electronics in automotive displays and lighting.             615
• Table 202. Printed and flexible electronics are being integrated into vehicle interiors.       616
• Table 203. Applications of curved displays in automotive and technology readiness level (TRL).     621
• Table 204. Companies developing curved automotive displays.   622
• Table 205. Applications of Micro-LED in automotive.        626
• Table 206. HUD vs other display types.   628
• Table 207. Automotive display Mini-LED and Micro-LED products.              630
• Table 208. Conductive materials for transparent capacitive sensors.          634
• Table 209. Automotive applications for printed piezoresistive sensors.    635
• Table 210.  Piezoelectric sensors for automotive applications.      636
• Table 211. Printed piezoelectric sensors in automotive applications.         636
• Table 212. SWIR for autonomous mobility and ADAS.       638
• Table 213. Types of printed photodetectors and image sensors developed for automotive applications     639
• Table 214. Comparison of SWIR image sensors technologies         640
• Table 215. Comparison of conventional and printed seat heaters for automotive applications.      641
• Table 216. Printed car seat heaters.         641
• Table 217. Types of Printed/flexible interior heaters.       642
• Table 218. Transparent heaters for exterior lighting / sensors / windows.               645
• Table 219. Types of transparent heaters for automotive exterior applications.      645
• Table 220. Transparent electronics for automotive radar for ADAS.            646
• Table 221. Global market for printed and flexible automotive electronics, 2018-2034, millions of US dollars.           649
• Table 222. Market challenges for printed and flexible electronics in automotive. 650
• Table 223. Macro-trends in smart buildings and construction.      652
• Table 224. Market drivers for smart sensors for buildings.              653
• Table 225. Printed and flexible electronics being applied for building, infrastructure, and industrial applications.   655
• Table 226.  Printed electronics in customizable smart building interiors.  656
• Table 227. Types of smart building sensors.          657
• Table 228. Commonly used sensors in smart buildings.    658
• Table 229. Capacitive sensors integrated into smart buildings.      660
• Table 230. Types of flexible humidity sensors.     661
• Table 231. MOF sensor applications.        664
• Table 232. Global market for printed and flexible smart buildings electronics, 2018-2034, millions of US dollars.    668
• Table 233. Consumer goods applications for printed/flexible electronics. 676
• Table 234. Types of Active packaging.      679
• Table 235. Commercially available food active packaging.               680
• Table 236. Types of intelligent packaging.              681
• Table 237. Types of RFID tags.    683
• Table 238.  Commercially available time-temperature indicators (TTI) indicators. 685
• Table 239. Commercially available freshness indicators.  687
• Table 240. Commercially available gas indicators.               688
• Table 241.  Supply chain management considerations for smart electronic packaging targeted at consumers.         690
• Table 242. Types of printed/flexible electronics and materials that can be used to enhance packaging barcodes.   697
• Table 243. Commercially available freshness indicators.  701
• Table 244. Commercial examples of time-temperature indicators               701
• Table 245. Examples of Chemical Time Temperature Indicators (TTIs).      703
• Table 246. Types of ripeness indicators. 703
• Table 247. Commercially available gas indicators.               705
• Table 248. Chemical sensors in smart packaging. 705
• Table 249. Electrochemical-based sensors for smart food packaging.         706
• Table 250. Optical-based sensors for smart food packaging applications. 706
• Table 251. Electrochemical biosensors for smart food packaging:                707
• Table 252. Optical-Based Biosensors for smart food packaging.    707
• Table 253. Types of edible sensors for food packaging.    708
• Table 254.  Commercially available radio frequency identification systems (RFID) technology.       714
• Table 255. Passive RFID: Technologies by Operating Frequency.  715
• Table 256. Examples of NFC in packaging.              718
• Table 257. Companies in smart blister packs.       720
• Table 258. Global market for printed and flexible smart packaging electronics, 2018-2034, millions of US dollars.  720
• Table 259. 3DOM separator.       727
• Table 260. Battery performance test specifications of J. Flex batteries.     994
• Table 261. TCL Mini-LED product range. 1214

List of Figures

• Figure 1. Examples of flexible electronics devices.             79
• Figure 2. Evolution of electronics.             80
• Figure 3. Applications for printed and flexible electronics.              82
• Figure 4. Wearable technology inventions.           83
• Figure 5. Market map for printed and flexible electronics.              99
• Figure 6. Wove Band.     101
• Figure 7. Wearable graphene medical sensor.     102
• Figure 8. 3D printed stretchable electronics.        103
• Figure 9. Artificial skin prototype for gesture recognition.              106
• Figure 10. Applications of wearable flexible sensors worn on various body parts. 107
• Figure 11. Systemization of wearable electronic systems.               108
• Figure 12. Baby Monitor.              115
• Figure 13. Wearable health monitor incorporating graphene photodetectors.      116
• Figure 14. LG 77” transparent 4K OLED TV.            117
• Figure 15. 137-inch N1 foldable TV.          118
• Figure 16. Flex Note Extendable™.           118
• Figure 17. Flex In & Out Flip.        119
• Figure 18. Traxcon printed lighting circuitry.         126
• Figure 19. Global market revenues for Printed & Flexible consumer electronics, 2018-2034, (millions USD).             130
• Figure 20. Global market for Printed & Flexible medical & healthcare electronics, 2018-2034, millions of US dollars.                131
• Figure 21. Global market for Printed & Flexible E-textiles and smart apparel electronics, 2018-2034, millions of US dollars. 132
• Figure 22. Global market for Printed & Flexible displays, 2018-2034, millions of US dollars.              133
• Figure 23. Global market for Printed & Flexible automotive electronics, 2018-2034, millions of US dollars.                134
• Figure 24. Global market for Printed & Flexible smart buildings electronics, 2018-2034, millions of US dollars.        135
• Figure 25. Global market for Printed & Flexible smart packaging electronics, 2018-2034, millions of US dollars       136
• Figure 26. SWOT analysis for printed electronics.               140
• Figure 27. SWOT analysis for 3D electronics.        144
• Figure 28. SWOT analysis for analogue printing.  147
• Figure 29. SWOT analysis for digital printing.        150
• Figure 30. In-mold electronics prototype devices and products.   150
• Figure 31. SWOT analysis for In-Mold Electronics.              154
• Figure 32. SWOT analysis for R2R manufacturing.              158
• Figure 33. The molecular mechanism of the shape memory effect under different stimuli.              164
• Figure 34. Supercooled Soldering™ Technology. 169
• Figure 35. Reflow soldering schematic.   170
• Figure 36. Schematic diagram of induction heating reflow.            171
• Figure 37. Types of conductive inks and applications.       174
• Figure 38. Copper based inks on flexible substrate.           180
• Figure 39. SWOT analysis for Printable semiconductors. 186
• Figure 40.  SWOT analysis for Printable sensor materials.                191
• Figure 41. RFID Tag with Nano Copper Antenna on Paper.              193
• Figure 42. SWOT analysis for flexible integrated circuits. 202
• Figure 43. Fully-printed organic thin-film transistors and circuitry on one-micron-thick polymer films.        202
• Figure 44. Flexible PCB. 205
• Figure 45. SWOT analysis for Flexible batteries.  209
• Figure 46.  SWOT analysis for Flexible PV for energy harvesting.  212
• Figure 47. SWOT analysis for printed, flexible and hybrid electronics in consumer electronics.       218
• Figure 48. EmeTerm nausea relief wearable.        223
• Figure 49. Embr Wave for cooling and warming. 224
• Figure 50. dpl Wrist Wrap Light THerapy pain relief.         225
• Figure 51. SWOT analysis for Wrist-worn wearables.        226
• Figure 52. FitBit Sense Watch.    227
• Figure 53. Wearable bio-fluid monitoring system for monitoring of hydration.      232
• Figure 54. Nuheara IQbuds² Max.             236
• Figure 55. HP Hearing PRO OTC Hearing Aid.        238
• Figure 56. SWOT analysis for Ear worn wearables (hearables).     241
• Figure 57. Beddr SleepTuner.     247
• Figure 58. Global market revenues for printed and flexible in consumer electronics, 2018-2034, (millions USD).    253
• Figure 59. SWOT analysis for printed, flexible and hybrid electronics in medical and healthcare/wellness. 260
• Figure 60. Connected human body and product examples.            261
• Figure 61. Companies and products in wearable health monitoring and rehabilitation devices and products.           268
• Figure 62. Smart e-skin system comprising health-monitoring sensors, displays, and ultra flexible PLEDs.  275
• Figure 63. Graphene medical patch.         278
• Figure 64. Graphene-based E-skin patch.               278
• Figure 65. SWOT analysis for printed and flexible electronics in skin patches.        283
• Figure 66. Enfucell wearable temperature tag.    284
• Figure 67. TempTraQ wearable wireless thermometer.   285
• Figure 68. Technologies for minimally-invasive and non-invasive glucose detection.           286
• Figure 69. Schematic of non-invasive CGM sensor.            291
• Figure 70. Adhesive wearable CGM sensor.          291
• Figure 71. VitalPatch.     296
• Figure 72. Wearable ECG-textile.              296
• Figure 73. Wearable ECG recorder.           297
• Figure 74. Nexkin™.        298
• Figure 75. Bloomlife.      300
• Figure 76. Nanowire skin hydration patch.             301
• Figure 77. NIX sensors.  301
• Figure 78. Wearable sweat sensor.           302
• Figure 79. Wearable  graphene sweat sensor.     303
• Figure 80. Gatorade's GX Sweat Patch.   303
• Figure 81. Sweat sensor incorporated into face mask.      304
• Figure 82. D-mine Pump.              305
• Figure 83. Lab-on-Skin™.              306
• Figure 84. My UV Patch. 307
• Figure 85. Overview layers of L'Oreal skin patch. 308
• Figure 86. Brilliantly Warm.          309
• Figure 87. Ava Fertility tracker.   310
• Figure 88. S9 Pro breast pump.  310
• Figure 89. Tempdrop.    310
• Figure 90. Digitsole Smartshoe. 311
• Figure 91. Schematic of smart wound dressing.  314
• Figure 92. REPAIR electronic patch concept. Image courtesy of the University of Pittsburgh School of Medicine.    315
• Figure 93. ABENA Nova smart diaper.      316
• Figure 94. Honda Walking Assist.               317
• Figure 95. ABLE Exoskeleton.      318
• Figure 96. ANGEL-LEGS-M10.      318
• Figure 97. AGADEXO Shoulder.  318
• Figure 98. Enyware.        319
• Figure 99. AWN-12 occupational powered hip exoskeleton.          319
• Figure 100. CarrySuit passive upper-body exoskeleton.   319
• Figure 101. Axosuit lower body medical exoskeleton.      320
• Figure 102. FreeGait.      320
• Figure 103. InMotion Arm.           320
• Figure 104. Biomotum SPARK.    320
• Figure 105. PowerWalk energy. 321
• Figure 106. Keeogo™.    321
• Figure 107. MATE-XT.     321
• Figure 108. CDYS passive shoulder support exoskeleton. 322
• Figure 109. ALDAK.          322
• Figure 110. HAL® Lower Limb.     322
• Figure 111. DARWING PA.            322
• Figure 112. Dephy ExoBoot.        323
• Figure 113. EksoNR.        323
• Figure 114. Emovo Assist.             323
• Figure 115. HAPO.           324
• Figure 116. Atlas passive modular exoskeleton.  324
• Figure 117. ExoAtlet II.   324
• Figure 118. ExoHeaver. 325
• Figure 119. Exy ONE.      325
• Figure 120. ExoArm.       325
• Figure 121. ExoMotus.   326
• Figure 122. Gloreha Sinfonia.      326
• Figure 123. BELK Knee Exoskeleton.         326
• Figure 124. Apex exosuit.             327
• Figure 125. Honda Walking Assist.            327
• Figure 126. BionicBack.  327
• Figure 127. Muscle Suit. 328
• Figure 128.Japet.W powered exoskeleton.           328
• Figure 129.Ski~Mojo.     328
• Figure 130. AIRFRAME passive shoulder. 329
• Figure 131.FORTIS passive tool holding exoskeleton.        329
• Figure 132. Integrated Soldier Exoskeleton (UPRISE®).     329
• Figure 133.UNILEXA passive exoskeleton.             330
• Figure 134.HandTutor.   330
• Figure 135.MyoPro®.      330
• Figure 136.Myosuit.        330
• Figure 137. archelis wearable chair.          331
• Figure 138.Chairless Chair.           331
• Figure 139.Indego.          331
• Figure 140. Polyspine.    332
• Figure 141. Hercule powered lower body exoskeleton.   332
• Figure 142. ReStore Soft Exo-Suit.             332
• Figure 143. Hand of Hope.           333
• Figure 144. REX powered exoskeleton.   333
• Figure 145. Elevate Ski Exoskeleton.        333
• Figure 146. UGO210 exoskeleton.            333
• Figure 147. EsoGLOVE Pro.           334
• Figure 148. Roki.               334
• Figure 149. Powered Clothing.   334
• Figure 150. Againer shock absorbing exoskeleton.             334
• Figure 151. EasyWalk Assistive Soft Exoskeleton Walker. 335
• Figure 152. Skel-Ex.         335
• Figure 153. EXO-H3 lower limbs robotic exoskeleton.      335
• Figure 154. Ikan Tilta Max Armor-Man 2 336
• Figure 155. AMADEO hand and finger robotic rehabilitation device.          336
• Figure 156.Atalante autonomous lower-body exoskeleton.           336
• Figure 157. Global market for printed and flexible medical & healthcare electronics, 2018-2034, millions of US dollars.                337
• Figure 158. SWOT analysis for printed, flexible and hybrid electronics in E-textiles.             345
• Figure 159. Timeline of the different generations of electronic textiles.   347
• Figure 160. Examples of each generation of electronic textiles.    347
• Figure 161. Conductive yarns.     352
• Figure 162. H-Tee by H-Cube.     354
• Figure 163. Electronics integration in textiles: (a) textile-adapted, (b) textile-integrated (c) textile-basd.   355
• Figure 164. Stretchable polymer encapsulation microelectronics on textiles.         361
• Figure 165. Conductive yarns.     364
• Figure 166. Classification of conductive materials and process technology.             365
• Figure 167. Structure diagram of Ti3C2Tx.              376
• Figure 168. Structure of hexagonal boron nitride.              376
• Figure 169. BN nanosheet textiles application.    378
• Figure 170. SEM image of cotton fibers with PEDOT:PSS coating. 380
• Figure 171. Schematic of inkjet-printed processes.            385
• Figure 172: Silver nanocomposite ink after sintering and resin bonding of discrete electronic components.             392
• Figure 173. Schematic summary of the formulation of silver conductive inks.         393
• Figure 174. Copper based inks on flexible substrate.         395
• Figure 175: Schematic of single-walled carbon nanotube.              399
• Figure 176. Stretchable SWNT memory and logic devices for wearable electronics.             399
• Figure 177. Graphene layer structure schematic. 401
• Figure 178. BGT Materials graphene ink product.               402
• Figure 179. PCM cooling vest.     406
• Figure 180. SMPU-treated cotton fabrics.              407
• Figure 181. Schematics of DIAPLEX membrane.  407
• Figure 182. SMP energy storage textiles.               408
• Figure 183. Nike x Acronym Blazer Sneakers.       413
• Figure 184. Adidas 3D Runner Pump.       413
• Figure 185. Under Armour Archi-TechFuturist.    413
• Figure 186. Reebok Reebok Liquid Speed.             413
• Figure 187. Radiate sports vest. 414
• Figure 188. Adidas smart insole. 418
• Figure 189. Applications of E-textiles.      422
• Figure 190. EXO2 Stormwalker 2 Heated Jacket. 424
• Figure 191. Flexible polymer-based heated glove, sock and slipper.            426
• Figure 192. ThermaCell Rechargeable Heated Insoles.     426
• Figure 193. Myant sleeve tracks biochemical indicators in sweat. 429
• Figure 194. Flexible polymer-based therapeutic products.             429
• Figure 195. iStimUweaR .              430
• Figure 196. Digitsole Smartshoe.               434
• Figure 197. Basketball referee Royole fully flexible display.            436
• Figure 198. A mechanical glove, Robo-Glove, with pressure sensors and other sensors jointly developed by General Motors and NASA.           438
• Figure 199. Power supply mechanisms for electronic textiles and wearables.        439
• Figure 200. Micro-scale energy scavenging techniques.  443
• Figure 201. Schematic illustration of the fabrication concept for textile-based dye-sensitized solar cells (DSSCs) made by sewing textile electrodes onto cloth or paper.               445
• Figure 202. 3D printed piezoelectric material.      447
• Figure 203. Application of electronic textiles in AR/VR.    449
• Figure 204. Global market for printed and flexible E-textiles and smart apparel electronics, 2018-2034, millions of US dollars. 452
• Figure 205. SWOT analysis for printed, flexible and hybrid electronics in energy. 457
• Figure 206. Flexible batteries on the market.       458
• Figure 207. ULTRALIFE thin film battery. 462
• Figure 208. Examples of applications of thin film batteries.            464
• Figure 209. Capacities and voltage windows of various cathode and anode materials.        465
• Figure 210. Traditional lithium-ion battery (left), solid state battery (right).            467
• Figure 211. Bulk type compared to thin film type SSB.      470
• Figure 212. Ragone plots of diverse batteries and the commonly used electronics powered by flexible batteries.  473
• Figure 213. Flexible, rechargeable battery.           474
• Figure 214. Various architectures for flexible and stretchable electrochemical energy storage.      475
• Figure 215. Types of flexible batteries.   477
• Figure 216. Flexible label and printed paper battery.        478
• Figure 217. Materials and design structures in flexible lithium ion batteries.          481
• Figure 218. Flexible/stretchable LIBs with different structures.    483
• Figure 219. Schematic of the structure of stretchable LIBs.             484
• Figure 220. Electrochemical performance of materials in flexible LIBs.      485
• Figure 221. a–c) Schematic illustration of coaxial (a), twisted (b), and stretchable (c) LIBs. 487
• Figure 222. a) Schematic illustration of the fabrication of the superstretchy LIB based on an MWCNT/LMO composite fiber and an MWCNT/LTO composite fiber. b,c) Photograph (b) and the schematic illustration (c) of a stretchable fiber-shaped battery under stretching conditions. d) Schematic illustration of the spring-like stretchable LIB. e) SEM images of a fiberat different strains. f) Evolution of specific capacitance with strain. d–f) 489
• Figure 223. Origami disposable battery. 490
• Figure 224. Zn–MnO2 batteries produced by Brightvolt.  492
• Figure 225. Charge storage mechanism of alkaline Zn-based batteries and zinc-ion batteries.         495
• Figure 226. Zn–MnO2 batteries produced by Blue Spark. 495
• Figure 227. Ag–Zn batteries produced by Imprint Energy.               496
• Figure 228. Transparent batteries.            501
• Figure 229. Degradable batteries.             503
• Figure 230. Schematic of supercapacitors in wearables.  505
• Figure 231. (A) Schematic overview of a flexible supercapacitor as compared to conventional supercapacitor.        506
• Figure 232. Stretchable graphene supercapacitor.             507
• Figure 233.  Wearable self-powered devices.       510
• Figure 234. Various applications of printed paper batteries.          512
• Figure 235.Schematic representation of the main components of a battery.          512
• Figure 236. Schematic of a printed battery in a sandwich cell architecture, where the anode and cathode of the battery are stacked together.     514
• Figure 237. Manufacturing Processes for Conventional Batteries (I), 3D Microbatteries (II), and 3D-Printed Batteries (III).       527
• Figure 238. Main printing methods for supercapacitors.  531
• Figure 239. Schematic illustration of the fabrication concept for textile-based dye-sensitized solar cells (DSSCs) made by sewing textile electrodes onto cloth or paper.               542
• Figure 240. Origami-like silicon solar cells.             543
• Figure 241. Schematic illustration of the fabrication concept for textile-based dye-sensitized solar cells (DSSCs) made by sewing textile electrodes onto cloth or paper.               544
• Figure 242. Global market for printed and flexible energy storage, generation and harvesting electronics, 2018-2034, millions of US dollars.     548
• Figure 243. LG Signature OLED TV R.        552
• Figure 244. Flexible display.         553
• Figure 245. SWOT analysis for printed and flexible displays.          554
• Figure 246. f-OLED N-shaped folding display.       555
• Figure 247. C SEED 37-inch N1 foldable TV.           555
• Figure 248. DELL Ori.       555
• Figure 249. Gloshine curved LED screen. 556
• Figure 250. Huawei Mate X3.      556
• Figure 251. LG Media Chair.         557
• Figure 252. LG Virtual Ride.          557
• Figure 253. Microsoft     Surface Duo 2 .  558
• Figure 254. Motorola Razr.           558
• Figure 255. Mirage smart speaker with wraparound touch display.             559
• Figure 256. Samsung Galaxy Fold.             559
• Figure 257. Vivo X Flip.   561
• Figure 258. Organic LCD with a 10-mm bend radius.          563
• Figure 259. Foldable organic light-emitting diode (OLED) panel.   563
• Figure 260. AMOLED schematic. 566
• Figure 261. LG rollable OLED TV. 567
• Figure 262. OLED structure.         569
• Figure 263. AU Optonics Flexible MicroLED Display.           570
• Figure 264. Schematic of the TALT technique for wafer-level microLED transferring.           571
• Figure 265. Foldable 4K C SEED M1.          571
• Figure 266. Stamp-based transfer-printing techniques.   573
• Figure 267: Flexible & stretchable LEDs based on quantum dots. 574
• Figure 268. Samsung S-foldable display. 575
• Figure 269. Samsung slideable display.    576
• Figure 270. Samsung foldable battery patent schematic. 577
• Figure 271. Rollable 65RX OLED TV.          578
• Figure 272. Lenovo ThinkPad X1 Fold.      578
• Figure 273. LG Chem foldable display.     579
• Figure 274. Samsung Display Flex G folding smartphones.              579
• Figure 275. Asus Foldable Phone.              580
• Figure 276. Asus Zenbook 17 Fold.            580
• Figure 277. Dell Concept Ori.       581
• Figure 278. Intel Foldable phone.              581
• Figure 279. ThinkPad X1 Fold.     582
• Figure 280. Motorola Razr.           582
• Figure 281. Oppo Find N folding phone. 583
• Figure 282. Oppo Find N2 Flip.    583
• Figure 283. Royole FlexPai 2.       583
• Figure 284. Royole FlexPai 3 from CES 2024.         584
• Figure 285. Galaxy Fold 3.             584
• Figure 286. Samsung Galaxy Z Flip 3         584
• Figure 287. TCL Tri-Fold Foldable Phone 585
• Figure 288. TCL rollable phone.  585
• Figure 289. Xiaomi Mi MIX Flex. 586
• Figure 290. LG OLED flexible lighting panel.          587
• Figure 291. Flexible OLED incorporated into automotive headlight.            588
• Figure 292. Audi 2022 A8 .            589
• Figure 293. Electrophoretic display applications. 591
• Figure 294. Passive reflective displays with flexibility.       592
• Figure 295. Plastic Logic 5.4” Iridis™ display.         593
• Figure 296. Argil electrochromic film integrated with polycarbonate lenses.          594
• Figure 297. Transparent and flexible metamaterial film developed by Sekishi Chemical.    599
• Figure 298. Scanning electron microscope (SEM) images of several metalens antenna forms.         600
• Figure 299. Design concepts of soft mechanical metamaterials with large negative swelling ratios and tunable stress-strain curves.     602
• Figure 300. Different transparent displays and transmittance limitations. 604
• Figure 301. 7.56" high transparency & frameless Micro-LED display.          605
• Figure 302. AUO's 13.5-inch transparent RGB microLED display.  605
• Figure 303. 17.3-inch transparent microLED AI display in a Taiwan Ferry. 606
• Figure 304. Global market for printed and flexible displays, 2018-2034, millions of US dollars.        608
• Figure 305. SWOT analysis for printed, flexible and hybrid electronics in automotive.        611
• Figure 306. Automotive display concept.               616
• Figure 307. Mercedes MBUX Hyperscreen.           617
• Figure 308.  AUO Smart Cockpit with 55-inch pillar-to-pillar curved display.            622
• Figure 309. Cadillac XT4 33-inch curved LED touchscreen display 622
• Figure 310. Continental Curved Ultrawide Display.             622
• Figure 311. Hyundai 2024 Sonata panoramic curved display.         623
• Figure 312. Peugeot 3008 fastback SUV curved wide-screen display.         623
• Figure 313. TCL CSOT single, continuous flexible curved automotive display panel.              624
• Figure 314. AUO automotive display.       625
• Figure 315. Micro-LED automotive display.           625
• Figure 316. Issues in current commercial automotive HUD.           628
• Figure 317. Rear lamp utilizing flexible Micro-LEDs.           630
• Figure 318. SWOT analysis for integrated antennas with printed electronics in automotive.            649
• Figure 319. Global market for printed and flexible automotive electronics, 2018-2034, millions of US dollars.          650
• Figure 320. SWOT analysis for printed, flexible and hybrid electronics in smart buildings and construction. Source: Future Markets.               655
• Figure 321. Use of sensors in smart buildings.      658
• Figure 322. Global market for printed and flexible smart buildings electronics, 2018-2034, millions of US dollars.  669
• Figure 323. Active and Intelligent packaging classification.              671
• Figure 324. Smart packaging for detecting bacteria growth in milk containers.      672
• Figure 325. RFID tags with printed silver antennas on paper substrates.   674
• Figure 326. Smart card incorporating an ultra-thin battery.            682
• Figure 327. RFID ultra micro battery.       685
• Figure 328. SWOT analysis for printed, flexible and hybrid electronics in smart packaging.               690
• Figure 329. Active packaging film.             692
• Figure 330. Anti-counterfeiting smart label.          693
• Figure 331. Security tag developed by Nanotech Security.             697
• Figure 332. Fundamental principle of a gas sensor for detecting CO2 (gas) after food spoilage        704
• Figure 333. A standard RFID system.        710
• Figure 334. RFID functions and applications of silver nanoparticle inks.     710
• Figure 335. OHMEGA Conductive Ink + Touchcode box.   712
• Figure 336. Wiliot RFID. 713
• Figure 337. Smart blister pack.   719
• Figure 338. Global market for printed and flexible smart packaging electronics, 2018-2034, millions of US dollars. 722
• Figure 339. 24M battery.              724
• Figure 340. 3DOM battery.          727
• Figure 341. Libre 3.          729
• Figure 342. Abbott Lingo wearable.          730
• Figure 343. Libre Sense Glucose Sport Biowearable.         730
• Figure 344. AC biode prototype. 731
• Figure 345. AcuPebble SA100.    732
• Figure 346. Vitalgram®. 739
• Figure 347. BioMan+.     747
• Figure 348. EXO Glove.  747
• Figure 349. e-Tint® cell in the (a) OFF and in the (b) ON states.     749
• Figure 350. Alertgy NICGM wristband.    751
• Figure 351. ALLEVX.        752
• Figure 352. Gastric Alimetry.       753
• Figure 353. Alva Health stroke monitor. 758
• Figure 354. amofit S.       760
• Figure 355. Ampcera’s all-ceramic dense solid-state electrolyte separator sheets (25 um thickness, 50mm x 100mm size, flexible and defect free, room temperature ionic conductivity ~1 mA/cm).   761
• Figure 356. Amprius battery products.    762
• Figure 357. MIT and Amorepacific's chip-free skin sensor.              764
• Figure 358. All-polymer battery schematic.           766
• Figure 359. All Polymer Battery Module. 766
• Figure 360. Resin current collector.          766
• Figure 361. Sigi™ Insulin Management System.   768
• Figure 362. The Apollo wearable device. 770
• Figure 363. Apos3.           771
• Figure 364. Piezotech® FC.           774
• Figure 365. PowerCoat® paper. 776
• Figure 366. Artemis is  smart clothing system.     777
• Figure 367. KneeStim.    778
• Figure 368. LED hooded jacket.  782
• Figure 369. Heated element module.      783
• Figure 370. Ateios thin-film, printed battery.       786
• Figure 371. 1.39-inch full-circle Micro-LED display              789
• Figure 372. 9.4" flexible Micro-LED display.           790
• Figure 373. Cyclops HMD.             791
• Figure 374. PaciBreath.  794
• Figure 375. Avery Dennison smart labels.               796
• Figure 376. AD Pure™ Line [Sustainable UHF RFID tags and inlays].             796
• Figure 377. Structure of Azalea Vision’s smart contact lens.           798
• Figure 378. BeFC® biofuel cell and digital platform.           803
• Figure 379. Belun® Ring.                805
• Figure 380. Evo Patch.    810
• Figure 381. Neuronaute wearable.           814
• Figure 382. biped.ai device.         816
• Figure 383. 3D printed lithium-ion battery.           818
• Figure 384. Blue Solution module.            821
• Figure 385. TempTraq wearable patch.   822
• Figure 386. BOE Mini-LED display TV.       826
• Figure 387. BOE Mini-LED automotive display.     827
• Figure 388. circul+ smart ring.     829
• Figure 389. Brewer Science printed water sensor.             833
• Figure 390. C2Sense sensors.      835
• Figure 391. Cala Trio.      837
• Figure 392. Transparent 3D touch control with LED lights and LED matrix.               838
• Figure 393. Large transparent heater for LiDAR.  838
• Figure 394. Cionic Neural Sleeve.              847
• Figure 395. Carhartt X-1 Smart Heated Vest.        850
• Figure 396. Coachwhisperer device.        852
• Figure 397. Cognito's gamma stimulation device.               854
• Figure 398. Cogwear headgear. 855
• Figure 399. CardioWatch 287.     856
• Figure 400. Graphene dress. The dress changes colour in sync with the wearer’s breathing.           863
• Figure 401. Cymbet EnerChip™  864
• Figure 402. Descante Solar Thermo insulated jacket.        866
• Figure 403. G+ Graphene Aero Jersey.    867
• Figure 404. Diabeloop wearable.               871
• Figure 405. Inkjet printed OPV module.  875
• Figure 406. First Relief.  877
• Figure 407. FRENZ™ Brainband. 880
• Figure 408. NightOwl Home Sleep Apnea Test Device.     882
• Figure 409. Jewel Patch Wearable Cardioverter Defibrillator .       885
• Figure 410. P-Flex® Flexible Circuit.          886
• Figure 411. enFuse.        894
• Figure 412. Roll-to-roll equipment working with ultrathin steel substrate.              896
• Figure 413. EOPatch.      898
• Figure 414. Epilog.           901
• Figure 415. eQ02+LIfeMontor.   903
• Figure 416. noDiffusion OLED encapsulation film.               904
• Figure 417. TAeTTOOz printable battery materials.            909
• Figure 418. FDK Corp battery.     915
• Figure 419. Cove wearable device.           917
• Figure 420. HiFlex strain/pressure sensor.            919
• Figure 421. FloPatch.      922
• Figure 422. KiTT motion tracking knee sleeve.     927
• Figure 423. 2D paper batteries.  934
• Figure 424. 3D Custom Format paper batteries.  934
• Figure 425. Fuji carbon nanotube products.         935
• Figure 426. German bionic exoskeleton. 939
• Figure 427. UnlimitedHand.         949
• Figure 428. Healables app-controlled electrotherapy device.        953
• Figure 429. Helio materials incorporated into flexible displays.    955
• Figure 430. Apex Exosuit.             957
• Figure 431. Hinge Health wearable therapy devices.         959
• Figure 432. MYSA - 'Relax Shirt'. 961
• Figure 433. Humanox Shin Guard.             965
• Figure 434. Airvida E1.    966
• Figure 435. Sensor surface.          971
• Figure 436. ZincPoly™ technology.            973
• Figure 437. In2tec’s fully recyclable flexible circuit board assembly.           974
• Figure 438. Footrax.        975
• Figure 439. Flexible microLED.    978
• Figure 440. eMacula®.   979
• Figure 441. Printed moisture sensors.     983
• Figure 442. G2 Pro.          987
• Figure 443. Atusa system.            989
• Figure 444. ITEN micro batteries.              990
• Figure 445. Soluboard immersed in water.            996
• Figure 446. Infineon PCB before and after immersion.     997
• Figure 447. Kenzen ECHO Smart Patch.   1002
• Figure 448. The Kernel Flow headset.      1003
• Figure 449. REFLEX.         1005
• Figure 450. KnowU™.     1006
• Figure 451. Hyperfluorescence™ OLED display.   1012
• Figure 452. LiBEST flexible battery.           1020
• Figure 453. LifeSpan patch.          1023
• Figure 454. Ring ZERO.   1028
• Figure 455. LumeoLoop device. 1033
• Figure 456. Lyten batteries.         1034
• Figure 457. Mawi Heart Patch.   1038
• Figure 458. WalkAid.       1042
• Figure 459. Monarch™ Wireless Wearable Biosensor       1043
• Figure 460. MetaSCOPE.               1044
• Figure 461. HICARDI system.       1046
• Figure 462. Modoo device.          1053
• Figure 463. Movesense ECG monitor.      1055
• Figure 464. Munevo Drive.           1060
• Figure 465. Electroskin integration schematic.     1066
• Figure 466. Modius Sleep wearable device.          1074
• Figure 467. Neuphony Headband.            1075
• Figure 468. Nextiles’ compression garments.       1077
• Figure 469. Nextiles e-fabric.      1078
• Figure 470. Nix Biosensors patch.              1081
• Figure 471. Ayo wearable light therapy. 1083
• Figure 472. Nowatch.     1085
• Figure 473 .Nuada.          1090
• Figure 474. ONA DM.      1097
• Figure 475. ORII smart ring.          1099
• Figure 476. Otolith wearable device.       1103
• Figure 477. Oxitone 1000M.         1105
• Figure 478. Palarum PUP smart socks.     1108
• Figure 479. BEYOLEX™ film.         1109
• Figure 480. 55” flexible AM panel.            1110
• Figure 481. Peerbridge Cor.         1113
• Figure 482. 9.4" flexible MicroLED display.            1118
• Figure 483. 7.56-inch transparent Micro LED display.        1118
• Figure 484. Point Fit Technology skin patch.         1121
• Figure 485. Printed battery.         1124
• Figure 486. Printed Energy flexible battery.          1126
• Figure 487. Proxxi Voltage.          1130
• Figure 488. ProLogium solid-state battery.            1132
• Figure 489. Sylvee 1.0.   1138
• Figure 490. RealWear HMT-1.     1141
• Figure 491. RootiRx.        1144
• Figure 492. Micro-LED stretchable display.            1145
• Figure 493. Sylvee 1.0.   1148
• Figure 494. SES Apollo batteries.               1160
• Figure 495. Silvertree Reach.       1172
• Figure 496. Flexible Cover Window (FCWTM).     1176
• Figure 497. Smardii smart diaper.              1180
• Figure 498. Moonwalkers from Shift Robotics Inc.              1183
• Figure 499. SnowCookie device. 1186
• Figure 500. Softmatter compression garment.    1187
• Figure 501. Softmatter sports bra with a woven ECG sensor.         1187
• Figure 502. Soter device.              1188
• Figure 503. Femsense patch.      1195
• Figure 504. MoCap Pro Glove.    1199
• Figure 505. Subcuject.   1200
• Figure 506. 3D printed electronics.           1206
• Figure 507. Tactotek IME device.               1208
• Figure 508. TactoTek® IMSE® SiP - System In Package.     1209
• Figure 509. TCL Mini-LED TV schematic. 1214
• Figure 510. TCL 8K Mini-LED TV. 1214
• Figure 511. The Cinema Wall Micro-LED display. 1215
• Figure 512. Teslasuit.      1222
• Figure 513. Nerivio.         1225
• Figure 514. Feelzing Energy Patch.            1227
• Figure 515. 7.56” Transparent Display.    1228
• Figure 516. 7.56" Flexible Micro-LED.       1229
• Figure 517. 5.04" seamless splicing Micro LED.    1229
• Figure 518. 7.56" Transparent Micro LED.              1230
• Figure 519. A sample of TracXon’s printed lighting circuitry.           1237
• Figure 520. Ultrahuman wearable glucose monitor.          1239
• Figure 521. Vaxxas patch.             1242
• Figure 522. S-Patch Ex.   1258
• Figure 523. Wiliot tags.  1262
• Figure 524. Zeit Medical Wearable Headband.    1269
• Figure 525. ZOZOFIT wearable at-home 3D body scanner.              1272
• Figure 526. YouCare smart shirt. 1274

The Global Market for Printed and Flexible Electronics 2024-2034

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