Stretchable Electronics (SC) is already commercial and comes in many shapes and forms. The panel of images below showcases a number of prototypes and products which utilize a stretchable component and/or material. These pictures have been mainly (not entirely) taken by our analysts at events around the world during the past five years.
Out of each category in the panel below, multiple products have progressed past prototyping and are already on the market. Indeed, our report Stretchable and Conformal Electronics 2019-2029 finds that the stretchable and conformal electronics market will grow from a small base today to approach $500m within a decade at the level of materials and components. This quoted forecast value includes all the diverse markets which fall under the overarching umbrella term of SCE. The report itself, however, provides market segmentation by application as well as material/component type (14 categories).
The images below suggest that the nearly-commercialized or commercialized cases are varied. For example, InMold Electronics products are beginning to enter the market again. These products rely on the ability of functional materials to undergo a major one-off stretching event. Various fitness products utilising stretchable conductors as electrodes monitoring the heartrate or as respiratory sensors are already on the market and selling. Similar products are being applied to monitor pregnancy or to monitor the vital signs of animals. Many are also working on stretchable interconnects or printed circuit boards. Here too, a number of products are already on the market.
These cases suggest that most commercial growth comes from the use of relatively simple stretchable electronic elements such as electrodes, circuit lines and interconnects, and basic sensors. As a result, keeping it technologically simple seems to be a prerequisite for success at this phase of technology development. This is despite the fact researchers have demonstrated, at the proof-of-concept or basic demonstrator level, a stretchable version of almost every electronic device, including transistors, displays, batteries, memories, energy harvesters, and so on. For now, however, these complex devices remain very immature.
Our report Stretchable and Conformal Electronics 2019-2029 provides a detailed analysis of the market. It provides the most comprehensive and insightful view of this diverse emerging technology front, discussing each of the different stretchable materials/components available and/or being developed today, referencing over 60 product types that may integrate stretchable electronics, covering the progress of more than 100 companies and 25 research institutes including first-hand primary research on 62 companies, and providing ten-year market forecasts segmented by more than 14 material/component areas.
To learn more specifically about how stretchable electronics can be applied to the health and wellness sectors, attend IDTechEx's conference Healthcare Sensor Innovations. The conference and table-top exhibition, to be held September 25-26 in Cambridge, UK, focuses on how emerging technologies are being utilized in continuous health monitoring and point-of-care diagnostics. Stretchable electronics players Quad Industries and Holst/TNO will both be speaking and exhibiting at the conference.
The panel of images above shows various prototypes and products utilising some form of stretchable material and/or component. Most of these images have been taken by our analysts over the past five years in Taiwan, Japan, Korea, USA, Germany, and elsewhere. To learn more specifically about how stretchable electronics can be applied to the health and wellness sectors, attend IDTechEx's conference Healthcare Sensor Innovations
Setting up to identify and solve problems
Stretchable electronics faces a complicated path to the market. It is not a replacement market in that stretchable electronics will often not substitute an existing component or product. There are rare exceptions, for example, in e-textiles. However, even in those cases, the addressable market itself is nascent and fragmented. As such, the challenge is to create new markets and new demand.
This will require identifying and defining problems, in diverse sectors, which the unique features of stretchable electronics can help solve. This is no easy feat as it requires excellent access and insight to potential end users. This will demand patient and creative end product design around specific challenges. The fact that both (a) new technologies are to be utilized and (b) new customer needs are to be envisioned and created will act as a barrier, prolonging the go-to-market timelines.
This is a major challenge for most conventional firms accustomed to participating in existing and established markets and value chains. It is a particular challenge for the typical organizations who are pushing the development and commercialization of stretchable electronic materials and components/devices. These firms often sit far from end users and do not have the organizational mindset, skillset, or set-up to design, create, and commercialize end products.
This type of challenge is of course not unique to stretchable electronics. We have observed similar challenges in other emerging technology areas. One example is in printed and flexible electronics. In the earlier days, the vast majority of the market participants were material or component suppliers. The end users who strongly engaged had faced an uphill struggle even to produce low-volume prototypes. They would often have to assemble a small consortium of disparate and small firms with incompatible technologies and unrealistic claims. The path to the market was therefore, by no means, streamlined and the translation of concepts, even when they existed, to marketable products was complicated, time-consuming, and often expensive. This was a damper on the growth prospects and this challenge has taken years to be mitigated. As a result of this challenge, most early successes came not in new product creation, but in successfully replacing a component within an existing product.
The positive side is that the problems to be solved are numerous and exist in every sector. The lowest hanging fruits have so far been in fitness monitoring of persons and animals. InMold Electronics also offers a compelling proposition, despite its production learning curve being rather steep. The next round of products might come in smart skin patches and specialized patient monitoring tools, in protective or AR/VR clothing, and even in specialized textiles for automotive.
To learn more about stretchable and conformal electronics consult our report Stretchable and Conformal Electronics 2019-2029. This report is the result of years of global primary research on stretchable electronics itself, but also on its constituent elements and target applications. For example, IDTechEx analysts have covered topics such as conductive inks, in-mold electronics, electronic textiles, flexible/stretchable printed circuit boards, wearable technologies, stretchable sensors, stretchable transparent conductive films, structural electronics and more.
Top image: University of Windsor