Category Archives: technology

Carbethium, a better-than-scifi material

How to build one of these for real:

Light_bridge

Halo light bridge, from halo.wikia.com

Or indeed one of these:

From halo.wikia.com

From halo.wikia.com

I recently tweeted that I had an idea how to make the glowy bridges and shields we’ve seen routinely in sci-fi games from Half Life to Destiny, the bridges that seem to appear in a second or two from nothing across a divide, yet are strong enough to drive tanks over, and able to vanish as quickly and completely when they are switched off. I woke today realizing that with a bit of work, that it could be the basis of a general purpose material to make the tanks too, and buildings and construction platforms, bridges, roads and driverless pod systems, personal shields and city defense domes, force fields, drones, planes and gliders, space elevator bases, clothes, sports tracks, robotics, and of course assorted weapons and weapon systems. The material would only appear as needed and could be fully programmable. It could even be used to render buildings from VR to real life in seconds, enabling at least some holodeck functionality. All of this is feasible by 2050.

Since it would be as ethereal as those Halo structures, I first wanted to call the material ethereum, but that name was already taken (for a 2014 block-chain programming platform, which I note could be used to build the smart ANTS network management system that Chris Winter and I developed in BT in 1993), and this new material would be a programmable construction platform so the names would conflict, and etherium is too close. Ethium might work, but it would be based on graphene and carbon nanotubes, and I am quite into carbon so I chose carbethium.

Ages ago I blogged about plasma as a 21st Century building material. I’m still not certain this is feasible, but it may be, and it doesn’t matter for the purposes of this blog anyway.

https://timeguide.wordpress.com/2013/11/01/will-plasma-be-the-new-glass/

Around then I also blogged how to make free-floating battle drones and more recently how to make a Star Wars light-saber.

https://timeguide.wordpress.com/2013/06/23/free-floating-ai-battle-drone-orbs-or-making-glyph-from-mass-effect/

https://timeguide.wordpress.com/2015/11/25/how-to-make-a-star-wars-light-saber/

Carbethium would use some of the same principles but would add the enormous strength and high conductivity of graphene to provide the physical properties to make a proper construction material. The programmable matter bits and the instant build would use a combination of 3D interlocking plates, linear induction,  and magnetic wells. A plane such as a light bridge or a light shield would extend from a node in caterpillar track form with plates added as needed until the structure is complete. By reversing the build process, it could withdraw into the node. Bridges that only exist when they are needed would be good fun and we could have them by 2050 as well as the light shields and the light swords, and light tanks.

The last bit worries me. The ethics of carbethium are the typical mixture of enormous potential good and huge potential for abuse to bring death and destruction that we’re learning to expect of the future.

If we can make free-floating battle drones, tanks, robots, planes and rail-gun plasma weapons all appear within seconds, if we can build military bases and erect shield domes around them within seconds, then warfare moves into a new realm. Those countries that develop this stuff first will have a huge advantage, with the ability to send autonomous robotic armies to defeat enemies with little or no risk to their own people. If developed by a James Bond super-villain on a hidden island, it would even be the sort of thing that would enable a serious bid to take over the world.

But in the words of Professor Emmett Brown, “well, I figured, what the hell?”. 2050 values are not 2016 values. Our value set is already on a random walk, disconnected from any anchor, its future direction indicated by a combination of current momentum and a chaos engine linking to random utterances of arbitrary celebrities on social media. 2050 morality on many issues will be the inverse of today’s, just as today’s is on many issues the inverse of the 1970s’. Whatever you do or however politically correct you might think you are today, you will be an outcast before you get old: https://timeguide.wordpress.com/2015/05/22/morality-inversion-you-will-be-an-outcast-before-youre-old/

We’re already fucked, carbethium just adds some style.

Graphene combines huge tensile strength with enormous electrical conductivity. A plate can be added to the edge of an existing plate and interlocked, I imagine in a hexagonal or triangular mesh. Plates can be designed in many diverse ways to interlock, so that rotating one engages with the next, and reversing the rotation unlocks them. Plates can be pushed to the forward edge by magnetic wells, using linear induction motors, using the graphene itself as the conductor to generate the magnetic field and the design of the structure of the graphene threads enabling the linear induction fields. That would likely require that the structure forms first out of graphene threads, then the gaps between filled by mesh, and plates added to that to make the structure finally solid. This would happen in thickness as well as width, to make a 3D structure, though a graphene bridge would only need to be dozens of atoms thick.

So a bridge made of graphene could start with a single thread, which could be shot across a gap at hundreds of meters per second. I explained how to make a Spiderman-style silk thrower to do just that in a previous blog:

https://timeguide.wordpress.com/2015/11/12/how-to-make-a-spiderman-style-graphene-silk-thrower-for-emergency-services/

The mesh and 3D build would all follow from that. In theory that could all happen in seconds, the supply of plates and the available power being the primary limiting factors.

Similarly, a shield or indeed any kind of plate could be made by extending carbon mesh out from the edge or center and infilling. We see that kind of technique used often in sci-fi to generate armor, from lost in Space to Iron Man.

The key components in carbetheum are 3D interlocking plate design and magnetic field design for the linear induction motors. Interlocking via rotation is fairly easy in 2D, any spiral will work, and the 3rd dimension is open to any building block manufacturer. 3D interlocking structures are very diverse and often innovative, and some would be more suited to particular applications than others. As for linear induction motors, a circuit is needed to produce the travelling magnetic well, but that circuit is made of the actual construction material. The front edge link between two wires creates a forward-facing magnetic field to propel the next plates and convey enough intertia to them to enable kinetic interlocks.

So it is feasible, and only needs some engineering. The main barrier is price and material quality. Graphene is still expensive to make, as are carbon nanotubes, so we won’t see bridges made of them just yet. The material quality so far is fine for small scale devices, but not yet for major civil engineering.

However, the field is developing extremely quickly because big companies and investors can clearly see the megabucks at the end of the rainbow. We will have almost certainly have large quantity production of high quality graphene for civil engineering by 2050.

This field will be fun. Anyone who plays computer games is already familiar with the idea. Light bridges and shields, or light swords would appear much as in games, but the material would likely  be graphene and nanotubes (or maybe the newfangled molybdenum equivalents). They would glow during construction with the plasma generated by the intense electric and magnetic fields, and the glow would be needed afterward to make these ultra-thin physical barriers clearly visible,but they might become highly transparent otherwise.

Assembling structures as they are needed and disassembling them just as easily will be very resource-friendly, though it is unlikely that carbon will be in short supply. We can just use some oil or coal to get more if needed, or process some CO2. The walls of a building could be grown from the ground up at hundreds of meters per second in theory, with floors growing almost as fast, though there should be little need to do so in practice, apart from pushing space vehicles up so high that they need little fuel to enter orbit. Nevertheless, growing a  building and then even growing the internal structures and even furniture is feasible, all using glowy carbetheum. Electronic soft fabrics, cushions and hard surfaces and support structures are all possible by combining carbon nanotubes and graphene and using the reconfigurable matter properties carbethium convents. So are visual interfaces, electronic windows, electronic wallpaper, electronic carpet, computers, storage, heating, lighting, energy storage and even solar power panels. So is all the comms and IoT and all the smart embdedded control systems you could ever want. So you’d use a computer with VR interface to design whatever kind of building and interior furniture decor you want, and then when you hit the big red button, it would appear in front of your eyes from the carbethium blocks you had delivered. You could also build robots using the same self-assembly approach.

If these structures can assemble fast enough, and I think they could, then a new form of kinetic architecture would appear. This would use the momentum of the construction material to drive the front edges of the surfaces, kinetic assembly allowing otherwise impossible and elaborate arches to be made.

A city transport infrastructure could be built entirely out of carbethium. The linear induction mats could grow along a road, connecting quickly to make a whole city grid. Circuit design allows the infrastructure to steer driverless pods wherever they need to go, and they could also be assembled as required using carbethium. No parking or storage is needed, as the pod would just melt away onto the surface when it isn’t needed.

I could go to town on military and terrorist applications, but more interesting is the use of the defense domes. When I was a kid, I imagined having a house with a defense dome over it. Lots of sci-fi has them now too. Domes have a strong appeal, even though they could also be used as prisons of course. A supply of carbetheum on the city edges could be used to grow a strong dome in minutes or even seconds, and there is no practical limit to how strong it could be. Even if lasers were used to penetrate it, the holes could fill in in real time, replacing material as fast as it is evaporated away.

Anyway, lots of fun. Today’s civil engineering projects like HS2 look more and more primitive by the day, as we finally start to see the true potential of genuinely 21st century construction materials. 2050 is not too early to expect widespread use of carbetheum. It won’t be called that – whoever commercializes it first will name it, or Google or MIT will claim to have just invented it in a decade or so, so my own name for it will be lost to personal history. But remember, you saw it here first.

Cellular blockchain, cellular bitcoin

Bitcoin has been around a while and the blockchain foundations on which it is built are extending organically into other areas.

Blockchain is a strongly encrypted distributed database, a ledger that records every transaction. That’s all fine, it works OK, and it doesn’t need fixed.

However, for some applications or new cryptocurrencies, there may be some benefit in making a cellular blockchain to limit database size, protect against network outage, and harden defenses against any local decryption. These may become important as cyber-terrorism increases and as quantum computing develops. They would also be more suited to micro-transactions and micro-currencies.

If you’ve made it this far, you almost certainly don’t need any further explanation.

Diabetes: Electronically controlled drug delivery via smart membrane

This is an invention I made in 2001 as part of my active skin suite to help diabetics. I’ve just been told I am another of the zillions of diabetics in the world so was reminded of it.

This wasn’t feasible in 2001 but it will be very soon, and could be an ideal way of monitoring blood glucose and insulin levels, checking with clinic AI for the correct does, and then opening the membrane pores just enough and long enough to allow the right dose of insulin to pass through. Obviously pore and drug particle design have to be coordinated, but this should be totally feasible. Here’s some pics:

Active skin principles

Active skin principles

Drug delivery overview

Drug delivery overview

Drug delivery mechanism

Drug delivery mechanism

New book: Society Tomorrow

It’s been a while since my last blog. That’s because I’ve been writing another book, my 8th so far. Not the one I was doing on future fashion, which went on the back burner for a while, I’ve only written a third of that one, unless I put it out as a very short book.

This one follows on from You Tomorrow and is called Society Tomorrow, 20% shorter at 90,000 words. It is ready to publish now, so I’m just waiting for feedback from a few people before hitting the button.

Frontcover

Here’s the introduction:

The one thing that we all share is that we will get older over the next few decades. Rapid change affects everyone, but older people don’t always feel the same effects as younger people, and even if we keep up easily today, some of us may find it harder tomorrow. Society will change, in its demographic and ethnic makeup, its values, its structure. We will live very differently. New stresses will come from both changing society and changing technology, but there is no real cause for pessimism. Many things will get better for older people too. We are certainly not heading towards utopia, but the overall quality of life for our ageing population will be significantly better in the future than it is today. In fact, most of the problems ahead are related to quality of life issues in society as a whole, and simply reflect the fact that if you don’t have to worry as much about poor health or poverty, something else will still occupy your mind.

This book follows on from 2013’s You Tomorrow, which is a guide to future life as an individual. It also slightly overlaps my 2013 book Total Sustainability which looks in part at future economic and social issues as part of achieving sustainability too. Rather than replicating topics, this book updates or omits them if they have already been addressed in those two companion books. As a general theme, it looks at wider society and the bigger picture, drawing out implications for both individuals and for society as a whole to deal with. There are plenty to pick from.

If there is one theme that plays through the whole book, it is a strong warning of the problem of increasing polarisation between people of left and right political persuasion. The political centre is being eroded quickly at the moment throughout the West, but alarmingly this does not seem so much to be a passing phase as a longer term trend. With all the potential benefits from future technology, we risk undermining the very fabric of our society. I remain optimistic because it can only be a matter of time before sense prevails and the trend reverses. One day the relative harmony of living peacefully side by side with those with whom we disagree will be restored, by future leaders of higher quality than those we have today.

Otherwise, whereas people used to tolerate each other’s differences, I fear that this increasing intolerance of those who don’t share the same values could lead to conflict if we don’t address it adequately. That intolerance currently manifests itself in increasing authoritarianism, surveillance, and an insidious creep towards George Orwell’s Nineteen Eighty-Four. The worst offenders seem to be our young people, with students seemingly proud of trying to ostracise anyone who dares agree with what they think is correct. Being students, their views hold many self-contradictions and clear lack of thought, but they appear to be building walls to keep any attempt at different thought away.

Altogether, this increasing divide, built largely from sanctimony, is a very dangerous trend, and will take time to reverse even when it is addressed. At the moment, it is still worsening rapidly.

So we face significant dangers, mostly self-inflicted, but we also have hope. The future offers wonderful potential for health, happiness, peace, prosperity. As I address the significant problems lying ahead, I never lose my optimism that they are soluble, but if we are to solve problems, we must first recognize them for what they are and muster the willingness to deal with them. On the current balance of forces, even if we avoid outright civil war, the future looks very much like a gilded cage. We must not ignore the threats. We must acknowledge them, and deal with them.

Then we can all reap the rich rewards the future has to offer.

It will be out soon.

Future sex, gender and design

This is a presentation I made for the Eindhoven Design Academy. It is mostly self-explanatory

Slide1

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The future of vacuum cleaners

Dyson seems pretty good in vacuum cleaners and may well have tried this and found it doesn’t work, but then again, sometimes people in an industry can’t see the woods for the trees so who knows, there may be something in this:

Our new pet cat Jess, loves to pick up soft balls with a claw and throw them, and catch them again. Retractable claws are very effective.IMG_6689- Jess (2)

Jess the cat

At a smaller scale, velcro uses tiny little hooks to stick together, copying burs from nature.

Suppose you make a tiny little ball that has even tinier little retractable spines or even better, hooks. And suppose you make them by the trillion and make a powder that your vacuum cleaner attachment first sprinkles onto a carpet, then agitates furiously and quickly, and thus gets the hooks to stick to dirt, pull it off the surface and retract (so that the balls don’t stick to the carpet) and then you suck the whole lot into the machine. Since the balls have a certain defined specification, they are easy to separate from the dirt and dust and reuse again straight away. So you get superior cleaning. Some of the balls would be lost each time, and some would get sucked up next time, but overall you’d need to periodically top up the reservoir.

The current approach is to beat the hell out of the carpet fibers with a spinning brush and that works fine, but I think adding the active powder might be better because it gets right in among the dirt and drags it kicking and screaming off the fibers.

So, ball design. Firstly, it doesn’t need to be ball shaped at all, and secondly it doesn’t need spines really, just to be able to rapidly change its shape so it gets some sort of temporary traction on a dirt particle to knock it off. What we need here is any structure that expands and contracts or dramatically changes shape when a force is applied, ideally resonantly. Two or three particles connected by a tether would move back and forwards under an oscillating electrostatic, electrical or magnetic field or even an acoustic wave. There are billions of ways of doing that and some would be cheaper than others to manufacture in large quantity. Chemists are brilliant at designing custom molecules with particular shapes, and biology has done that with zillions of enzymes too. Our balls would be pretty small but more micro-tech than nano-tech or molecular tech.

The vacuum cleaner attachment would thus spray this stuff onto the carpet and start resonating it with an EM field or sound waves. The little particles would wildly thrash around doing their micro-cleaning, yanking dirt free, and then they would be sucked back into the cleaner to be used again. The cleaner head doesn’t even need to have a spinning brush, the only moving parts would be the powder, though having an agitating brush might help get them deeper into the fabric I guess.

 

Smart packaging: Acoustic sterilisation

I should have written this on the ides of March, but hey ho. I was discussing packaging this morning for an IoT event.

Imagine a bacterium sitting on a package on a supermarket shelf is called Julius Caesar. Now imagine Brutus coming along with a particularly sharp knife and stabbing him hundreds of times. That’s my idea, just scaled down a bit.

selfsterilising

This started as a slight adaptation of an idea I developed for Dunlop a few years ago to make variable grip tires. (Still waiting for Dunlop to make those, so maybe some other tire company might pick up the idea).

The idea is very simple, to use tiny triangular structures embedded in the surface, and then pull the base of the triangle together, thereby pushing up the tip. My tire idea used electro-active polymers to do the pulling, and sharp carbon composites to do the grip bit, or in this antibacterial case, the sharp knife. Probably for packaging I’d use carbon nanotubes or similar as the sides with which to stab the bacteria, but engineers frequently come up with different nanostructure shapes so I’m pretty agnostic about material and shape. If it ruptures a bacterium, it will be good.

An easier to use alternative for widespread use in packaging would be to ditch the electro-active polymer and associated electronics, and instead to use a tuned acoustic wave to move the blades in and out of the surface. All that is needed to activate them is to put out that frequency of sound through a speaker system in the supermarket or factory. The sound needed would likely be ultrasonic, so it doesn’t irritate all the shoppers, and in any case, nano-structures will generally be associated with high frequencies.

So the packaging would include tiny structures that act as the dagger attached to a particular acoustic mass acting as Brutus, that would move when the appropriate resonant frequency is broadcast.

This technique doesn’t need any nasty chemicals, though it does need the nanostructures and sound and if they aren’t designed right, the nanostructures could be just as harmful. Anyway, that’s the basic idea.

Image

Self-sterilizing surfaces & packaging

selfsterilising

The future of mind control headbands

Have you ever wanted to control millions of other people as your own personal slaves or army? How about somehow persuading lots of people to wear mind control headbands, that you control? Once they are wearing them, you can use them as your slaves, army or whatever. And you could put them into offline mode in between so they don’t cause trouble.

Amazingly, this might be feasible. It just requires a little marketing to fool them into accepting a device with extra capabilities that serve the seller rather than the buyer. Lots of big companies do that bit all the time. They get you to pay handsomely for something such as a smartphone and then they use it to monitor your preferences and behavior and then sell the data to advertisers to earn even more. So we just need a similar means of getting you to buy and wear a nice headband that can then be used to control your mind, using a confusingly worded clause hidden on page 325 of the small print.

I did some googling about TMS- trans-cranial magnetic stimulation, which can produce some interesting effects in the brain by using magnetic coils to generate strong magnetic fields to create electrical currents in specific parts of your brain without needing to insert probes. Claimed effects vary from reducing inhibitions, pain control, activating muscles, assisting learning, but that is just today, it will be far easier to get the right field shapes and strengths in the future, so the range of effects will increase dramatically. While doing so, I also discovered numerous pages about producing religious experiences via magnetic fields too. I also recalled an earlier blog I wrote a couple of year ago about switching people off, which relied on applying high frequency stimulation to the claustrum region. https://timeguide.wordpress.com/2014/07/05/switching-people-off/

The source I cited for that is still online:  http://www.newscientist.com/article/mg22329762.700-consciousness-onoff-switch-discovered-deep-in-brain.html.

So… suppose you make a nice headband that helps people get in touch with their spiritual side. The time is certainly right. Millennials apparently believe in the afterlife far more than older generations, but they don’t believe in gods. They are begging for nice vague spiritual experiences that fit nicely into their safe spaces mentality, that are disconnected from anything specific that might offend someone or appropriate someone’s culture, that bring universal peace and love feelings without the difficult bits of having to actually believe in something or follow some sort of behavioral code. This headband will help them feel at one with the universe, and with other people, to be effortlessly part of a universal human collective, to share the feeling of belonging and truth. You know as well as I do that anyone could get millions of millennials or lefties to wear such a thing. The headband needs some magnetic coils and field shaping/steering technology. Today TMS uses old tech such as metal wires, tomorrow they will use graphene to get far more current and much better fields, and they will use nice IoT biotech feedback loops to monitor thoughts emotions and feelings to create just the right sorts of sensations. A 2030 headband will be able to create high strength fields in almost any part of the brain, creating the means for stimulation, emotional generation, accentuation or attenuation, muscle control, memory recall and a wide variety of other capabilities. So zillions of people will want one and happily wear it.  All the joys of spirituality without the terrorism or awkward dogma. It will probably work well with a range of legal or semi-legal smart drugs to make experiences even more rich. There might be a range of apps that work with them too, and you might have a sideline in a company supplying some of them.

And thanks to clause P325e paragraph 2, the headband will also be able to switch people off. And while they are switched off, unconscious, it will be able to use them as robots, walking them around and making them do stuff. When they wake up, they won’t remember anything about it so they won’t mind. If they have done nothing wrong, they have nothing to fear, and they are nor responsible for what someone else does using their body.

You could rent out some of your unconscious people as living statues or art-works or mannequins or ornaments. You could make shows with them, synchronised dances. Or demonstrations or marches, or maybe you could invade somewhere. Or get them all to turn up and vote for you at the election.  Or any of 1000 mass mind control dystopian acts. Or just get them to bow down and worship you. After all, you’re worth it, right? Or maybe you could get them doing nice things, your choice.

 

Pubic fashion and the Internet-of-genitalia

Not for the easily offended, or my parents, who do read my blog sometimes, but hopefully not this one. This is another extract from my forthcoming book on future fashion. No sector is immune to futurology.

The pubic area may not be talked about much in fashion articles, but it is suited to fashion as any other. Pubic hairstyles (including bald) vary from person to person and over time, but they certainly do get fashion consideration. Vajazzling, decorating the female pubic area with stick-on glitter, has also had its limelight as a fashion thing, Beautifying and styling the pubic area is here to stay for as long as casual sex remains common. If an area gets attention, people will want to make it look sexier or more interesting or enticing, so it is just another platform for personal expression, as much as choice of underwear.

Updating stick-on glitter to LEDs or lasers could make a whole light show down there. This could of course tap into data from sensors that pick up on sexual activity and arousal level. That would allow a direct feedback route on performance. Whoever is pleasuring her could see the results echoed in a visual response in local LEDs or flashing glitter or laser beams. That would be fun, but it could use audio too. Since the pubic region is fairly flat and firm, it also presents a potential surface for flat speakers to generate sound effects or music during sex, again linked to arousal sensor feedback. Of course, speakers are another form of vibration device too so they might also take an active role in stimulation.

Hair management already uses lasers to kill hair follicles, but some women regret having their pubic areas completely depilated, and are now having hair implanted back. As hair styles come and go, what is needed is a better trimming and shaving system. I am surprised the shaver industry has not already picked up on this possibility, (if it has I am not aware of it) but a design could be rendered much better if the shaver can access a local positioning system. If a person sticks on a few tiny transmitters, reflectors or transponders in specific places near the trimming zone, the shaver head would know its exact position and orientation and would be able to trim that specific area precisely as dictated by the chosen pattern. Automated precision hair styles would be feasible without taking too much time. Another cheap and easy way of doing this would be to spray a marker pattern through a stencil and have the shaver trim the areas marked.

Naturally, such shaver technology would also be useful for other areas such as the head or chest (for men anyway, I don’t expect female chest hair to be a significant fashion trend any time soon), or to replace waxing anywhere on the body with precision patterns and trims.

Many people are unhappy with their actual genitalia. Re-scuplting, trimming, tightening, or changing size is becoming common. Gender re-assignment surgery is also growing, but gender-change and gender-play fashion needs a whole section for itself, and I’ve written about it before anyway(my most popular post ever in fact) : https://timeguide.wordpress.com/2014/02/14/the-future-of-gender-2/

Not in the pubic area, but somewhat related  to this topic nonetheless, here is a quick consideration of smart breast implants:

[Smart breast implants

Smart breast implants are one of my best inventions – the only one for which I have ever received a prize. The idea was that if a woman is determined to expand her breasts by putting stuff into them, why not put electronics in? In fact, electronics can be made using silicone, one of the main breast implant materials. It won’t work as fast as silicon-based IT but it will do fine for things like MP3 players (MP4 now of course). A range of smartphone-style functions could be added as well as music playing. For example, navigation could link location and maps to vibrating nipples to indicate left or right. I suggested using nipples as control knobs for my MP3 implants, and that is perfectly feasible. Detectors in the implant could easily detect torsion and interpret the tweaks. Implants would be able to monitor some biological functions more precisely than wristbands. Heartbeat and breathing could be audio recorded far better for example.

Shape changing breast implants

I often cite polymer gel muscles in fashion, because they are so useful. Contracting when a voltage is applied across them, but made of electro-active polymer so they feel organic, they are ideal for many purposes in and on the body for extra strength of for changing shapes or orientation. Breast implants could contain strands of such gel, arranged so that the shape of the implant can be altered. They could be adjusted to change breast shape, improve lift or cleavage, and relaxed when no-one is looking.

Pectoral implants already give some men the appearance of being more muscular and fit. Adding actual strength using polymer gel muscles rather than simple padding would be a lot better.

Bras

Shape change materials could also be used in bras of course, allowing control to be varied by an app. A single bra could work for general and sports use for example. Similarly, hydraulic bras could give extra lift or control by inflating tubes with compressed air. Staying with inflation, of course the bra as a whole could be inflated to give the illusion of larger size.

Bras can incorporate energy harvesting for use while running. A suitable material could be plastic capacitors, which make electricity directly as they flex.

Nipple-tapes could be coupled to vibrators for a slightly more immersive sexual experience, and remote controlled for more kinky play.]

Now, back to the pubic area.

Rather along the same lines as smart breast implants, if someone is going to the lengths of having genital surgery and particularly if implants are involved, then electronic implants could be a useful consideration. Some devices use electrical stimulation, applying particular patterns of voltages and currents to create, magnify and sustain arousal. Devices could be implanted to do exactly this. They could be access restricted to the wearer, controlled by a dominant or even networked for remote control, by any chosen individual or group. MEMS or sensors could also be implanted to create vibration or to measure arousal.

Sensors can easily detect moisture levels, skin resistance, blood flow, blood oxygen levels, heart rate, breathing and so on. These together can indicate a great deal about arousal state and that can be fed back into stimulation system to maximise pleasure. Stimulation devices could provide direct stimulation or work along with external devices such as vibrators, controlling their behavior according to location and sensor feedback. Vibrators shouldn’t need control knobs that distract their users, but should automatically adjust their behavior according to the region they are stimulating and the user’s  arousal profile, changing stimulation throughout the session according to programs and recorded routines stored in the cloud. Shared toys could use fingerprint recognition or implanted RFID chips, but I think that would usually be considered to be going too far. 

An important fashion consideration is that visual appearance can mostly be decoupled from function. Electronics can be shrunk to vanishingly small size and fit in the tiniest of sensors or actuators. Genital and pubic electronics can therefore be visually appealing at the same time as providing a full suite of functionality.

Shape change materials such as electro-active polymers can also be implanted. These could also be used to generate vibration by varying applied voltage patterns appropriately. Shape changing implants could be used to vary tightness during penetration, or to make features more appealing during foreplay.

As with the pubic area as a whole, genitals could also incorporate visual feedback using color change, LEDS or even music or other sound effects according to arousal state. Sound is better generated by pubic speakers though as surfaces are more cooperative to engineering.

Clearly, with a number of feedback and bio-sign monitoring sensors, MEMS, speaker systems, illumination, decoration and visual effects systems, the whole pubic and genital region is a potentially large electronics ecosystem, and we will need a whole branch of IoT technology, which could be termed ‘Internet of genitalia’.