Instruction on how to install Girl Body Scanner on Windows 7/8/10 Pc & Laptop
In this post, I am going to show you how to install Girl Body Scanner on Windows PC by using Android App Player such as BlueStacks, Nox, KOPlayer, …
Below you will find a detailed step-by-step guide, but I want to give you a fast overview of how it works. All you need is an emulator that will emulate an Android device on your Windows PC and then you can install applications and use it – you see you’re playing it on Android, but this runs not on a smartphone or tablet, it runs on a PC.
Step By Step Guide To Install Girl Body Scanner using BlueStacks
Download and Install BlueStacks at: https://www.bluestacks.com. The installation procedure is quite simple. After successful installation, open the
Bluestacks emulator. It may take some time to load the Bluestacks app initially. Once it is opened, you should be able to see the Home screen of Bluestacks.
Google Play Store comes pre-installed in Bluestacks. On the home screen, find Google Play Store and click on the icon to open it. You may need to sign in to access the Play Store.
Look for “Girl Body Scanner” in the search bar. Click to install “Girl Body Scanner” from the search results.
If you don’t see this app from the search results, you need to download APK/XAPK installer file from this page, save it to an easy-to-find location. Once the APK/XAPK file is downloaded, double-click to open it. You can also drag and drop the APK/XAPK file onto the BlueStacks home screen to open it.
Once installed, click “Girl Body Scanner” icon on the home screen to start using, it’ll work like a charm đ
[Notes] about Bluetooth: At the moment, support for Bluetooth is not available on BlueStacks. Hence, apps that require control of Bluetooth may not work on BlueStacks.
How to install Girl Body Scanner on Windows PC using NoxPlayer
Download & Install NoxPlayer at: https://www.bignox.com. The installation is easy to carry out.
After NoxPlayer is installed, open it and you can see the search bar on the home screen. Look for “Girl Body Scanner” and click to install from the search results.
You can also download the APK/XAPK installer file from this page, then drag and drop it onto the NoxPlayer home screen. The installation process will take place quickly. After successful installation, you can find “Girl Body Scanner” on the home screen of NoxPlayer.
In this lens concept, an antenna at the periphery collects incoming RF energy from a separate portable transmitter. Power-conversion circuitry provides DC power to other parts of the system and sends instructions to the display control circuit. The display, at the center, might consist of LEDs, which would turn on and off, or LCD-like elements, whose transparency would be modulated by the control circuit. An energy-storage module, perhaps a large capacitor, is connected to a solar cell, which could provide a boost to the lens. A biosensor samples the surface of the cornea, performs an analysis, and provides data to the telecommunication module to transmit to an external computer.
A new generation of contact lenses built with very small circuits and LEDs promises bionic eyesight
BY Babak A. Parviz
IEEE Spec | The human eye is a perceptual powerhouse. It can see millions of colors, adjust easily to shifting light conditions, and transmit information to the brain at a rate exceeding that of a high-speed Internet connection.
But why stop there?
In the Terminator movies, Arnold Schwarzeneggerâs character sees the world with data superimposed on his visual fieldâvirtual captions that enhance the cyborgâs scan of a scene. In stories by the science fiction author Vernor Vinge, characters rely on electronic contact lenses, rather than smartphones or brain implants, for seamless access to information that appears right before their eyes.
These visions (if I may) might seem far-fetched, but a contact lens with simple built-in electronics is already within reach; in fact, my students and I are already producing such devices in small numbers in my laboratory at the University of Washington, in Seattle. These lenses donât give us the vision of an eagle or the benefit of running subtitles on our surroundings yet. But we have built a lens with one LED, which weâve powered wirelessly with RF. What weâve done so far barely hints at what will soon be possible with this technology.
Conventional contact lenses are polymers formed in specific shapes to correct faulty vision. To turn such a lens into a functional system, we integrate control circuits, communication circuits, and miniature antennas into the lens using custom-built optoelectronic components. Those components will eventually include hundreds of LEDs, which will form images in front of the eye, such as words, charts, and photographs. Much of the hardware is semitransparent so that wearers can navigate their surroundings without crashing into them or becoming disoriented. In all likelihood, a separate, portable device will relay displayable information to the lensâs control circuit, which will operate the optoelectronics in the lens.
These lenses donât need to be very complex to be useful. Even a lens with a single pixel could aid people with impaired hearing or be incorporated as an indicator into computer games. With more colors and resolution, the repertoire could be expanded to include displaying text, translating speech into captions in real time, or offering visual cues from a navigation system. With basic image processing and Internet access, a contact-lens display could unlock whole new worlds of visual information, unfettered by the constraints of a physical display.
Besides visual enhancement, noninvasive monitoring of the wearerâs biomarkers and health indicators could be a huge future market. Weâve built several simple sensors that can detect the concentration of a molecule, such as glucose. Sensors built onto lenses would let diabetic wearers keep tabs on blood-sugar levels without needing to prick a finger. The glucose detectors weâre evaluating now are a mere glimmer of what will be possible in the next 5 to 10 years. Contact lenses are worn daily by more than a hundred million people, and they are one of the only disposable, mass-market products that remain in contact, through fluids, with the interior of the body for an extended period of time. When you get a blood test, your doctor is probably measuring many of the same biomarkers that are found in the live cells on the surface of your eyeâand in concentrations that correlate closely with the levels in your bloodstream. An appropriately configured contact lens could monitor cholesterol, sodium, and potassium levels, to name a few potential targets. Coupled with a wireless data transmitter, the lens could relay information to medics or nurses instantly, without needles or laboratory chemistry, and with a much lower chance of mix-ups.
Three fundamental challenges stand in the way of building a multipurpose contact lens. First, the processes for making many of the lensâs parts and subsystems are incompatible with one another and with the fragile polymer of the lens. To get around this problem, my colleagues and I make all our devices from scratch. To fabricate the components for silicon circuits and LEDs, we use high temperatures and corrosive chemicals, which means we canât manufacture them directly onto a lens. That leads to the second challenge, which is that all the key components of the lens need to be miniaturized and integrated onto about 1.5 square centimeters of a flexible, transparent polymer. We havenât fully solved that problem yet, but we have so far developed our own specialized assembly process, which enables us to integrate several different kinds of components onto a lens. Last but not least, the whole contraption needs to be completely safe for the eye. Take an LED, for example. Most red LEDs are made of aluminum gallium arsenide, which is toxic. So before an LED can go into the eye, it must be enveloped in a biocompatible substance.
So far, besides our glucose monitor, weâve been able to batch-fabricate a few other nanoscale biosensors that respond to a target molecule with an electrical signal; weâve also made several microscale components, including single-crystal silicon transistors, radio chips, antennas, diffusion resistors, LEDs, and silicon photodetectors. Weâve constructed all the micrometer-scale metal interconnects necessary to form a circuit on a contact lens. Weâve also shown that these microcomponents can be integrated through a self-assembly process onto other unconventional substrates, such as thin, flexible transparent plastics or glass. Weâve fabricated prototype lenses with an LED, a small radio chip, and an antenna, and weâve transmitted energy to the lens wirelessly, lighting the LED. To demonstrate that the lenses can be safe, we encapsulated them in a biocompatible polymer and successfully tested them in trials with live rabbits.
Second Sight:
In recent trials, rabbits wore lenses containing metal circuit structures for 20 minutes at a time with no adverse effects.
Seeing the lightâLED lightâis a reasonable accomplishment. But seeing something useful through the lens is clearly the ultimate goal. Fortunately, the human eye is an extremely sensitive photodetector. At high noon on a cloudless day, lots of light streams through your pupil, and the world appears bright indeed. But the eye doesnât need all that optical powerâit can perceive images with only a few microwatts of optical power passing through its lens. An LCD computer screen is similarly wasteful. It sends out a lot of photons, but only a small fraction of them enter your eye and hit the retina to form an image. But when the display is directly over your cornea, every photon generated by the display helps form the image.
The beauty of this approach is obvious: With the light coming from a lens on your pupil rather than from an external source, you need much less power to form an image. But how to get light from a lens? Weâve considered two basic approaches. One option is to build into the lens a display based on an array of LED pixels; we call this an active display. An alternative is to use passive pixels that merely modulate incoming light rather than producing their own. Basically, they construct an image by changing their color and transparency in reaction to a light source. (Theyâre similar to LCDs, in which tiny liquid-crystal âshuttersâ block or transmit white light through a red, green, or blue filter.) For passive pixels on a functional contact lens, the light source would be the environment. The colors wouldnât be as precise as with a white-backlit LCD, but the images could be quite sharp and finely resolved.
Weâve mainly pursued the active approach and have produced lenses that can accommodate an 8-by-8 array of LEDs. For now, active pixels are easier to attach to lenses. But using passive pixels would significantly reduce the contactâs overall power needsâif we can figure out how to make the pixels smaller, higher in contrast, and capable of reacting quickly to external signals.
By now youâre probably wondering how a person wearing one of our contact lenses would be able to focus on an image generated on the surface of the eye. After all, a normal and healthy eye cannot focus on objects that are fewer than 10 centimeters from the corneal surface. The LEDs by themselves merely produce a fuzzy splotch of color in the wearerâs field of vision. Somehow the image must be pushed away from the cornea. One way to do that is to employ an array of even smaller lenses placed on the surface of the contact lens. Arrays of such microlenses have been used in the past to focus lasers and, in photolithography, to draw patterns of light on a photoresist. On a contact lens, each pixel or small group of pixels would be assigned to a microlens placed between the eye and the pixels. Spacing a pixel and a microlens 360 micrometers apart would be enough to push back the virtual image and let the eye focus on it easily. To the wearer, the image would seem to hang in space about half a meter away, depending on the microlens.
Another way to make sharp images is to use a scanning microlaser or an array of microlasers. Laser beams diverge much less than LED light does, so they would produce a sharper image. A kind of actuated mirror would scan the beams from a red, a green, and a blue laser to generate an image. The resolution of the image would be limited primarily by the narrowness of the beams, and the lasers would obviously have to be extremely small, which would be a substantial challenge. However, using lasers would ensure that the image is in focus at all times and eliminate the need for microlenses.
Whether we use LEDs or lasers for our display, the area available for optoelectronics on the surface of the contact is really small: roughly 1.2 millimeters in diameter. The display must also be semitransparent, so that wearers can still see their surroundings. Those are tough but not impossible requirements. The LED chips weâve built so far are 300 ”m in diameter, and the light-emitting zone on each chip is a 60-”m-wide ring with a radius of 112 ”m. Weâre trying to reduce that by an order of magnitude. Our goal is an array of 3600 10-”m-wide pixels spaced 10 ”m apart.
One other difficulty in putting a display on the eye is keeping it from moving around relative to the pupil. Normal contact lenses that correct for astigmatism are weighted on the bottom to maintain a specific orientation, give or take a few degrees. I figure the same technique could keep a display from tilting (unless the wearer blinked too often!).
Like all mobile electronics, these lenses must be powered by suitable sources, but among the options, none are particularly attractive. The space constraints are acute. For example, batteries are hard to miniaturize to this extent, require recharging, and raise the specter of, say, lithium ions floating around in the eye after an accident. A better strategy is gathering inertial power from the environment, by converting ambient vibrations into energy or by receiving solar or RF power. Most inertial power scavenging designs have unacceptably low power output, so we have focused on powering our lenses with solar or RF energy.
Letâs assume that 1 square centimeter of lens area is dedicated to power generation, and letâs say we devote the space to solar cells. Almost 300 microwatts of incoming power would be available indoors, with potentially much more available outdoors. At a conversion efficiency of 10 percent, these figures would translate to 30 ”W of available electrical power, if all the subsystems of the contact lens were run indoors.
Collecting RF energy from a source in the userâs pocket would improve the numbers slightly. In this setup, the lens area would hold antennas rather than photovoltaic cells. The antennasâ output would be limited by the field strengths permitted at various frequencies. In the microwave bands between 1.5 gigahertz and 100 GHz, the exposure level considered safe for humans is 1 milliwatt per square centimeter. For our prototypes, we have fabricated the first generation of antennas that can transmit in the 900-megahertz to 6-GHz range, and weâre working on higher-efficiency versions. So from that one square centimeter of lens real estate, we should be able to extract at least 100 ”W, depending on the efficiency of the antenna and the conversion circuit.
Having made all these subsystems work, the final challenge is making them all fit on the same tiny polymer disc. Recall the pieces that we need to cram onto a lens: metal microstructures to form antennas; compound semiconductors to make optoelectronic devices; advanced complementary metal-oxide-semiconductor silicon circuits for low-power control and RF telecommunication; microelectromechanical system (MEMS) transducers and resonators to tune the frequencies of the RF communication; and surface sensors that are reactive with the biochemical environment.
The semiconductor fabrication processes weâd typically use to make most of these components wonât work because they are both thermally and chemically incompatible with the flexible polymer substrate of the contact lens. To get around this problem, we independently fabricate most of the microcomponents on silicon-on-insulator wafers, and we fabricate the LEDs and some of the biosensors on other substrates. Each part has metal interconnects and is etched into a unique shape. The end yield is a collection of powder-fine parts that we then embed in the lens.
We start by preparing the substrate that will hold the microcomponents, a 100-”m-thick slice of polyethylene terephthalate. The substrate has photolithographically defined metal interconnect lines and binding sites. These binding sites are tiny wells, about 10 ”m deep, where electrical connections will be made between components and the template. At the bottom of each well is a minuscule pool of a low-melting-point alloy that will later join together two interconnects in what amounts to micrometer-scale soldering.
We then submerge the plastic lens substrate in a liquid medium and flow the collection of microcomponents over it. The binding sites are cut to match the geometries of the individual parts so that a triangular component finds a triangular well, a circular part falls into a circular well, and so on. When a piece falls into its complementary well, a small metal pad on the surface of the component comes in contact with the alloy at the bottom of the well, causing a capillary force that lodges the component in place. After all the parts have found their slots, we drop the temperature to solidify the alloy. This step locks in the mechanical and electrical contact between the components, the interconnects, and the substrate.
The next step is to ensure that all the potentially harmful components that weâve just assembled are completely safe and comfortable to wear. The lenses weâve been developing resemble existing gas-permeable contacts with small patches of a slightly less breathable material that wraps around the electronic components. Weâve been encapsulating the functional parts with poly(methyl methacrylate), the polymer used to make earlier generations of contact lenses. Then thereâs the question of the interaction of heat and light with the eye. Not only must the systemâs power consumption be very low for the sake of the energy budget, it must also avoid generating enough heat to damage the eye, so the temperature must remain below 45 °C. We have yet to investigate this concern fully, but our preliminary analyses suggest that heat shouldnât be a big problem.
All the basic technologies needed to build functional contact lenses are in place. Weâve tested our first few prototypes on animals, proving that the platform can be safe. What we need to do now is show all the subsystems working together, shrink some of the components even more, and extend the RF power harvesting to higher efficiencies and to distances greater than the few centimeters we have now. We also need to build a companion device that would do all the necessary computing or image processing to truly prove that the system can form images on demand. Weâre starting with a simple product, a contact lens with a single light source, and we aim to work up to more sophisticated lenses that can superimpose computer-generated high-resolution color graphics on a userâs real field of vision.
The true promise of this research is not just the actual system we end up making, whether itâs a display, a biosensor, or both. We already see a future in which the humble contact lens becomes a real platform, like the iPhone is today, with lots of developers contributing their ideas and inventions. As far as weâre concerned, the possibilities extend as far as the eye can see, and beyond.
The author would like to thank his past and present students and collaborators, especially Brian Otis, Desney Tan, and Tueng Shen, for their contributions to this research.
About the Author
Babak A. Parviz wakes up every morning and sticks a small piece of polymer in each eye. So it was only a matter of time before this bionanotechnology expert at the University of Washington, in Seattle, imagined contact lenses with built-in circuits and LEDs. âItâs really fun to hook things up and see how they might work,â he says. In âFor Your Eye Onlyâ, Parviz previews a contact lens for the 21st century.