Know your Body

Scientists have discovered a new organ 'Interstitium' in the human body, a discovery that could help  the scientists understand the spread of cancer within the body.

The findings of the study were published in the Nature's Scientific Reports journal on March 27, 2018.

The Study

• Scientists used a special live imaging technique called a Probe-based Confocal Laser Endomicroscopy (pCLE) to locate the interstitium in various parts of the body such as lungs and digestive tract.

• The study was conducted by David Carr-Locke and Petros Benias, doctors of Mount Sinai Beth Israel Medical Centre, while investigating patient's bile duct for cancer.

• The research team collected tissue specimens of bile ducts during twelve cancer surgeries that involved removal of pancreas and the bile duct.

The Findings

• The study reveals that layers of body 'Connective Tissues' that were long thought to be dense, lining the digestive tract, lungs and urinary systems and surrounding arteries and veins - are instead interconnected and fluid-filled compartments.

• These compartments have been termed as 'Interstitium' by the scientists.

• After a thorough study, scientists concluded that the interstitium can compress or expand in size, suggesting it could serve as "shock absorber" for other parts of the body.

• Once confirmed as an organ, interstitium will take skin’s place as the largest organ in the human body.

• Earlier, no one studied these spaces due to the medical field's dependence on the examination of fixed tissue on microscope slides to get the most accurate view of biological reality.

Scientists

https://www.jagranjosh.com/current-affairs/scientists-discover-a-new-organ-interstitium-in-the-human-body-1522404474-1

“The Fundamental Mistake in Physics Is of the Equation of Energy with Matter”

Norberto R. Keppe

This video will blow your mind! en de tr fr es it pt zh-hant ru

https://youtu.be/EqTV615IT9c

http://www.youtube.com/watch?v=H4xVuv...

Mehran Keshe fukushima

The New Physics Derived from a Disinverted Metaphysics, Dr. Norberto Keppe shows us how the inverted concepts in Physics (as well as biology and psychology) have proposed a totally upside down view of reality. Science has reached a dead-end because of the incorrect idea that energy comes from the electron, leading to the name “electronics.” In his follow up book to the New Physics, Magnetonics: The Science of Magnetism, Keppe expands on Nicola Tesla’s idea of the existence of essential energy (Tesla called it “scalar energy”), and it is this fundamental innovation that has led to the development of the Keppe Motor.

KEPPE MOTOR RECEIVES "2017 TECHNOLOGICAL INNOVATION POWER AWARD"

Both Teslas ans Keeper give free energy for the people

“Grand Prize”  e Keppe Motor Wins The Grand Prize of 17th HKEIA Award for Outstanding Innovation & Technology Products

The Keppe Motor has been tested and shown to use up to 90% less energy compared to traditional fractional single-phase AC induction motors, and is up to 20% more efficient than the latest electronically controlled DC brushless motors.

https://vimeo.com/181636313

Books that will help , http://www.keppemotor.com/institucional/publications-2/?lang=en

https://youtu.be/ONqey3rdb1Q

https://docs.google.com/document/d/1ceWRuooQNpMJjL_NAS4T0yInvskf49hFXAtj5tmmNqc/edit

Keshe Foundation

We are proud to announce that today 15.11.2012 the Nation of United States of America has received the USB stick containing all patents and blueprints of nuclear reactor plasma spaceship technology of the Keshe Foundation. http://www.keshefoundation.org/phpbb/...

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A Extra Video

https://youtu.be/WYEwZx9BwJ4

this will help in some experiment ........

For Beginners :

When building a robot, take the examples and add other techniques to improve the Robot much better, here I leave for beginners,  where to look for data,  some will spend a little money,  others will do it with household objects, the important thing is to do it,  According to what is requested and That works,  I leave the following link. some people are experts,  do not let that take away  your dream.

Robot Building for Beginners

Robot Building for Beginners. Building a robot can be challenging for the beginner, but stay with me and I will show you several ways that even a person with little or no technical knowledge can easily build robots.

The technologies of robotics run wide and deep. There is vision, robot intelligence, voice recognition, robot voice, robot locomotion (wheels, legged or flying robots), robot arm movement, just to name a few. In times past, if you were not an electronic engineer, a computer programmer, a mechanical engineer, and a person with hundreds of hours every month, you could not build a robot. Time and technology has changed all that. Robot building, even building robots from scratch has matured to a place where even a 12 year old average kid can build a robot in a short while--even faster that a 12 year old kid of 30 years ago could build a model boat or plane. It really has gotten a whole lot easier to build robots.

In the next few paragraphs I’m going to list out the easiest to the hardest way to build a robot. This will really be robot building for beginners. The harder ways will just be put there for reference. You as a robot hobbyist may never construct a scratch-built ‘bot, but it is nice to know a bit about how to do it. You will also see links to other robotic web pages that will give you more information on that type of robot building.

Pre-built Robots

The simplest robot to build is one that is already built. And by already built I’m not talking about some toys although some of the toys these days such as the Ultimate Wall-e as well as the R2D2 Mechanical ‘Droid are quite sophisticated pre-built robots. Another is Tomy’s humanoid robot the i-Sobot. These robots require little work aside from installing or charging a set of batteries. Sometimes the hardest work is just getting the darn 'bot out of its box. Robot building for beginners can include the challenge of box opening!

Competition Robots

The first pre-built robots worth talking about are the competition robots such as line following robots and sumo wrestling robots. While not many are not actually kits, they can introduce one to a lot of robotic concepts and some can be programmed. At a price point under $100 these “toys” are more sophisticated than many scratch built robots. They make easy robot building for beginners.

There are also Sumo Robot kits ranging from about $50 to more than $300. The Elenco OWI-9647 Sumo Robot that attempts to push other sumobots out of the arena that can be had for about $50.

Parallax’s Scribbler Robot is a “reprogrammable fully-assembled line following robot". You have the option of programming this little line following bot in the Scribbler Program Maker GUI (Graphical User Interface) language, a point and click graphically programming language. It is about $100 to build simple robots with this one.

Humanoid Beginners Robot Building

You think you can't build simple robots that look like people? The next level of robot building are complete kits are at an intermediate challenge for the robot builder. Like building a model car or plane, these all-in-one kits contain everything including step-by-step instructions, a person, even a 12 year old boy needs to construct a robot from parts alone. The Aldebaran Robotics Nao Humanoid Robot Academic Edition v3plus at more than $17,000 brings home robotics to a new and sophisticated level. This is robot building for beginners with STYLE!

Educational Robot Kits: VEX and Boe-Bots

Following the complete robot kits are the educational robotic kits. These are kits where the student can learn all about robot building while building several different version of robots. As with a lot of educational products, most are quite expensive. The top educational kits are the VEX robot kits which can take someone from no knowledge to a fairly sophisticated level of robotics in just a few weekends. Parallax.com says the Boe-Bot is the “most complete reprogrammable robot kit and is a great resource for STEM programs. No previous robotics, electronics, or programming experience is necessary.” At a bit over $150 it is a reasonably priced educational robotic system.

Leggo my Lego Minstorms Robot

Lego, the people that had kids putting up plastic sky scrapers since the 1940s, came up with a Lego robotics line of toys in 1998 and has been improving upon their Lego "brick" micro-controller ever since.

Finally it's time to discuss scratch builting robots vs. easy robot building. In the ancient times, say around 1980 or so, hobbyists were building robots of every size and shape. These scratch built robots usually were never “finished”, cost gobs of money, did little if anything useful, and took years of weekends to even get a basic robot to roll around a room. Most could not pick up anything. Many were dangerous, carrying along 12 volt car batteries, sloshing hydrochloric acid and spewing hydrogen gas which was expelled whenever one recharged them. They could cause an acid burn or even an explosion if one were not careful.

Click HERE to learn How to Build a Robot with Lego Mindstorms

We’ve come a long way from that and this author has come up with a method of scratch-building a robot that I call "super easy robot building." This uses a standard micro controller, servos for both robot arms and moving the robot around a room and plug-in range detectors to keep the little droids from slamming into walls, chairs and friends shins. See my robot building articles elsewhere on this site.

Click HERE to learn about robot building for beginners

The Newest Product for the Beginner: The EZ-Robot System

There is a new player on the beginner robot builder's block, and it's called the EZ-Robot. It claims to make robot building simple enough for kids and even frustrated adults. The world needed a better robot board and this might just be it. Click below to see a review of this intriguing new product and all that it promises.

EZ Robot Building with the EZ Robot Board

http://www.robots-and-androids.com/robot-building-for-beginners.html

Free......

Lessons Menu:

• Lesson 1 – Getting Started
• Lesson 2 – Choosing a Robotic Platform
• Lesson 3 – Making Sense of Actuators
• Lesson 4 – Understanding Microcontrollers
• Lesson 5 – Choosing a Motor Controller
• Lesson 6 – Controlling your Robot
• Lesson 7 – Using Sensors
• Lesson 8 – Getting the Right Tools
• Lesson 9 – Assembling a Robot
• Lesson 10 – Programming a Robot

Programming is usually the final step involved in building a robot. If you followed the lessons, so far you have chosen the actuators, electronics, sensors and more, and have assembled the robot so it hopefully looks something like what you had initially set out to build. Without programming though, the robot is a very nice looking and expensive paperweight.

It would take much more than one lesson to teach you how to program a robot, so instead, this lesson will help you with how to get started and where (and what) to learn. The practical example will use “Processing”, a popular hobbyist programming language intended to be used with the Arduino microcontroller chosen in previous lessons. We will also assume that you will be programming a microcontroller rather than software for a full-fledged computer.

What Language to Choose?

There are many programming languages which can be used to program microcontrollers, the most common of which are:

• Assembly ; its just one step away from machine code and as such it is very tedious to use. Assembly should only be used when you need absolute instruction-level control of your code.
• Basic; one of the first widely used programming languages, it is still used by some microcontrollers ( Basic Micro , BasicX , Parallax ) for educational robots.
• C / C++; one of the most popular languages, C provides high-level functionality while keeping a good low-level control.
• Java ; it is more modern than C and provides lots of safety features to the detriment of low-level control. Some manufacturers like Parallax make microcontrollers specifically for use with Java.
• .NET / C# ; Microsoft’s proprietary language used to develop applications in Visual Studio. Examples include Netduino , FEZ Rhino and others ).
• Processing ( Arduino ); a variant of C++ that includes some simplifications in order to make the programming for easier.
• Python , one of the most popular scripting languages. It is very simple to learn and can be used to put programs together very fast and efficiently.

In lesson 4 , you chose a microcontroller based on the features you needed (number of I/O, user community, special features, etc). Often times, a microcontroller is intended to be programmed in a specific language. For example:

• Arduino microcontrollers use Arduino software and are re-programmed in Processing .
• Basic Stamp microcontrollers use PBasic
• Basic Atom microcontrollers use Basic Micro
• Javelin Stamp from Parallax is programmed in Java

If you have chosen a hobbyist microcontroller from a known or popular manufacturer , there is likely a large book available so you can learn to program in their chosen programming language. If you instead chose a microcontroller from a smaller, lesser known manufacturer (e.g. since it had many features which you thought would be useful for your project), it’s important to see what language the controller is intended to be programmed in (C in many cases) and what development tools are there available (usually from the chip manufacturer).

Getting Started

The first program you will likely write is “Hello World” (referred to as such for historic reasons). This is one of the simplest programs that can be made in a computer and is intended to print a line of text (e.g. “Hello World”) on the computer monitor or LCD screen. In the case of a microcontroller, another very basic program you can do that has an effect on the outside world (rather than just on-board computations) is toggling an IO pin. Connecting an LED to and I/O pin then setting the I/O pin to ON and OFF will make the LED blink. Although the simple act of turning on an LED may seem basic, the function can allow for some complex programs (you can use it to light up multi-segment LEDs, to display text and numbers, operate relays, servos and more).

Step 1 : Ensure you have all components needed to program the microcontroller

Not all microcontrollers come with everything you need to program them, and most microcontrollers need to be connected to a computer via USB plug. If your microcontroller does not have a USB or DB9 connector, then you will need a separate USB to serial adapter, and wire it correctly. Fortunately many hobbyist microcontrollers are programmable either via an RS-232 port or by USB, and include the USB connector on-board which is used not only for two-way communication, but also to power the microcontroller board.

Step 2 : Connect the microcontroller to the computer and verify which COM port it is connected to. Not all microcontrollers will be picked up by the computer and you should read the “getting started” guide in the manual to know exactly what to do to have your computer recognize it and be able to communicate with it. You often need to download “drivers” (specific to each operating system) to allow your computer to understand how to communicate with the microcontroller and/or the USB to serial converter chip.

Step 3 : Check product’s user guide for sample code and communication method / protocol

Don’t reinvent the wheel if you don’t have to. Most manufacturers provide some code (or pseudo code) explaining how to get their product working. The sample code may not be in the programming language of your choice, but don’t despair; do a search on the Internet to see if other people have created the necessary code.

• Check product manuals / user guides
• Check the manufacturer’s forum
• Check the internet for the product + code
• Read the manual to understand how to write the code

Useful Tips

1. Create manageable chunks of functional code: By creating segments of code specific to each product, you gradually build up a library. Develop a file system on your computer to easily look up the necessary code.
2. Document everything within the code using comments: Documenting everything is necessary in almost all jobs, especially robotics. As you become more and more advanced, you may add comments to general sections of code, though as you start, you should add a comment to (almost) every line.
3. Save different versions of the code – do not always overwrite the same file: if you find one day that your 200+ lines of code do not compile, you won’t be stuck going through it line by line; instead you can revert to a previously saved (and functional) version and add / modify it as needed. Code does not take up much space o a hard drive, so you should not feel pressured to only save a few copies.
4. Raise the robot off the table or floor when debugging (so its wheels/ legs / tracks don’t accidentally launch it off the edge), and have the power switch close by in case the robot tries to destroy itself. An example of this is if you try to send a servo motor to a 400us signal when it only accepts a 500 (corresponding to 0 degrees) to 2500us (corresponding to 180 degrees) signal. The servo would try to move to a location which it cannot physically go to (-9 degrees) and ultimately burn out.
5. If code does something that does not seem to be working correctly after a few seconds, turn off the power – it’s highly unlikely the problem will “fix itself” and in the meantime, you may be destroying part of the mechanics.
6. Subroutines may be a bit difficult to understand at first, but they greatly simplify your code. If a segment of code is repeated many times within the code, it is a good candidate to be replaced with a subroutine.

Practical Example

We have chosen an Arduino microcontroller to be the “brain” of our robot. To get started, we can take a look at the Arduino 5 Minute Tutorials . These tutorials will help you use and understand the basic functionality of the Arduino programming language. Once you have finished these tutorials, take a look at the example below.

For the robot we have made, we will create code to have it move around (left, right, forward, reverse), move the two servos (pan/tilt) and communicate with the distance sensor. We chose Arduino because of the large user community, abundance of sample code and ease of integration with other products.

Distance sensor

Fortunately in the Arduino code, there is an example for getting values from an analog sensor. For this, we go to File -> Examples -> Analog -> AnalogInOutSerial (so we can see the values)

Pan/Tilt

Again, we are fortunate to have sample code to operate servos from an Arduino. File -> Examples ->  Servo -> Sweep

Note that text after two slashes // are comments and not part of the compiled code

#include // This loads the servo script, allowing you to use specific functions below

Servo myservo;                      // create servo object to control a servo
int pos = 0;                             // variable to store the servo position

void setup()                           // required in all Arduino code
{
myservo.attach(9);             // attaches the servo on pin 9 to the servo object
}

void loop()                               // required in all Arduino code
{
for(pos = 0; pos < 180; pos += 1)  // variable ‘pos’ goes from 0 degrees to 180 degrees in steps of 1 degree
{
myservo.write(pos);              // tell servo to go to position in variable ‘pos’
delay(15);                                 // waits 15ms for the servo to reach the position
}
for(pos = 180; pos>=1; pos-=1)     // variable ‘pos’ goes from 180 degrees to 0 degrees
{
myservo.write(pos);              // tell servo to go to position in variable ‘pos’
delay(15);                               // waits 15ms at each degree
}
}

Motor Controller

Here is where it gets a bit harder, since no sample code is available specifically for the Arduino. The controller is connected to the Tx (serial) pin of the Arduino and waits for a specific “start byte” before taking any action. The manual does indicate the communication protocol required; a string with specific structure:

• 0x80 (start byte)
• 0x00 (specific to this motor controller; if it receives anything else it will not take action)
• motor # and direction (motor one or two and direction explained in the manual)
• motor speed (hexadecimal from 0 to 127)

In order to do this, we create a character with each of these as bytes within the character:

unsigned char buff[6];

buff[0]=0x80; //start byte specific to Pololu motor controller
buff[1]=0; //Device type byte specific to this Pololu controller
buff[2]=1; //Motor number and direction byte; motor one =00,01
buff[3]=127; //Motor speed “0 to 128” (ex 100 is 64 in hex)

Serial.write(buff);

Therefore when this is sent via the serial pin, it will be sent in the correct order.

Putting all the code together makes the robot move forward and sweep the servo while reading distance values.

You can see the full robot and the user manual .

https://www.robotshop.com/blog/en/how-to-make-a-robot-lesson-10-programming-your-robot-2-3627

Great!

Thanks to climate change, seawater is something we're going to have plenty of in the future!

Researchers have achieved a major turning point in the quest for efficient desalination by announcing the invention of a graphene-oxide membrane that sieves salt right out of seawater.

At this stage, the technique is still limited to the lab, but it's a demonstration of how we could one day quickly and easily turn one of our most abundant resources, seawater, into one of our most scarce - clean drinking water.

The team, led by Rahul Nair from the University of Manchester in the UK, has shown that the sieve can efficiently filter out salts, and now the next step is to test this against existing desalination membranes.

"Realisation of scalable membranes with uniform pore size down to atomic scale is a significant step forward and will open new possibilities for improving the efficiency of desalination technology," says Nair .

"This is the first clear-cut experiment in this regime. We also demonstrate that there are realistic possibilities to scale up the described approach and mass produce graphene-based membranes with required sieve sizes."

Graphene-oxide membranes have long been considered a promising candidate for filtration and desalination, but although many teams have developed membranes that could sieve large particles out of water, getting rid of salt requires even smaller sieves that scientists have struggled to create.

One big issue is that, when graphene-oxide membranes are immersed in water, they swell up, allowing salt particles to flow through the engorged pores.

The Manchester team overcame this by building walls of epoxy resin on either side of the graphene oxide membrane, stopping it from swelling up in water.

This allowed them to precisely control the pore size in the membrane, creating holes tiny enough to filter out all common salts from seawater.

The key to this is the fact that when common salts are dissolved in water, they form a 'shell' of water molecules around themselves.

"Water molecules can go through individually, but sodium chloride cannot. It always needs the help of the water molecules," Nair told Paul Rincon from the BBC .

"The size of the shell of water around the salt is larger than the channel size, so it cannot go through."

Not only did this leave seawater fresh to drink, it also made the water molecules flow way faster through the membrane barrier, which is perfect for use in desalination.

"When the capillary size is around one nanometre, which is very close to the size of the water molecule, those molecules form a nice interconnected arrangement like a train," Nair explained to Rincon.

"That makes the movement of water faster: if you push harder on one side, the molecules all move on the other side because of the hydrogen bonds between them. You can only get that situation if the channel size is very small."

There are already several major desalination plants around the world using polymer-based membranes to filter out salt, but the process is still largely inefficient and expensive, so finding a way to make it quicker, cheaper, and easier is a huge goal for researchers.

Thanks to climate change, seawater is something we're going to have plenty of in the future - Greenland's coastal ice caps which have already passed the point of no return are predicted to increase sea levels by around 3.8 cm (1.5 inches) by 2100, and if the entire Greenland Ice Sheet melts, future generations will be facing oceans up to 7.3 metres (24 feet) higher.

But at the same time, clean drinking water is still incredibly hard to come by in many parts of the world - the UN predicts that by 2025, 14 percent of the world's population will encounter water scarcity. And many of those countries won't be able to afford large-scale desalination plants.

The researchers are now hoping that the graphene-based sieve might be as effective as large plants on the small scale, so it's easier to roll out.

Graphene oxide is also a lot easier and cheaper to make in the lab than single-layers of graphene, which means the technology will be affordable and easy to produce.

"The selective separation of water molecules from ions by physical restriction of interlayer spacing opens the door to the synthesis of inexpensive membranes for desalination," Ram Devanathan from the Pacific Northwest National Laboratory, who wasn't involved in the research, wrote in an accompanying Nature News and Views article .

"The ultimate goal is to create a filtration device that will produce potable water from seawater or wastewater with minimal energy input."

He added that the next step will be to test how durable the membranes are when used over long periods of time, and how often they need to be replaced.

The research has been published in Nature Nanotechnology .

Harnessing cosmic or zero-point energy is possible

Staff Writer

Waking Times

In a world of problems and solutions, few ideas spur both immediate hope and skepticism as the idea of free energy, and, on the brink of ecological disaster , nothing may be of greater importance to the human race.

The story of Nikola Tesla is a remarkable reminder of how our economic, political and media systems create our reality, because it shows how human ingenuity can be co-opted, shut-down, taken-over and hushed by powerful people with financial interests at stake. Fortunately, the legacy of Tesla lives on and people are now more interested than ever in his theories about cosmic energy and his patents for energy systems that could offer promise for liberating earth from dependence on fossil fuels.

Could it be that his vision has finally come to fruition and has been made available to the public, some 100 years after his patent for a fuel-less electricity generator?

“This new power for the driving of the world’s machinery will be derived from the energy which operates the universe, the cosmic energy, whose central source for the earth is the sun and which is everywhere present in unlimited quantities.” – Nikola Tesla

In March of 2014, a small group of independent engineers and developers released to the public open-source plans for a continuously running fuel-less electricity generator based on a patent by Nikola Tesla, and re-designed by inventor James Robitaille. Calling it the Quantum Energy Generator, or QEG, the portable device is supposedly capable of producing enough electricity to power a modern home, and is about the size and weight of a home gas generator.

“The Quantum Electric Generator system (QEG) is an adaptation of one of Nikola Tesla’s many patented electrical generator / dynamo / alternator designs. The particular patent referenced is No. 511,916, titled simply “Electric Generator”, and dated January 2, 1894 (see back of this manual). The adaptation is a conversion from a linear system, to a rotary system.

The QEG prototype is scaled to produce electrical power in the range of 10-15 kW (kilowatts) continuously, and can be set up to provide either 120 Volt or 230-240 Volt single phase output. We are also planning future designs to provide 3-phase power.” [ Fix The World ]

Developed by an organization known as the ‘ Fix the World Council ,’ and promoted by the lively Hopegirl , the prototype for the QEG was recently crowd-funded by over 600 independent contributors, and the plans for the QEG have been made available to the public for download here:

Download Plans for the Quantum Energy Generator here..

or Try this Link as well…

This means that the public now has access to the technical designs for this free-energy device, and if it works, and if it proves to be a viable option for creating electrical energy, then we may finally have the opportunity to bypass the energy monopoly and spread the technology of free energy to the world. In addition to downloading the publicly available open-source plans, people may also be able to purchase a pre-manufactured unit from an affiliated firm, so the race is now on for independent engineers and citizens to verify the efficacy of this declared revolution in energy.

“An effective way to understand the operating principal of the QEG is to think of it as a high-powered self-resonant oscillator (what they used to call a ‘multivibrator’), adapted to transform high-voltage pulses (15 to 25kV) into line voltage AC output, at current levels up to 120A.  In today’s alternative energy terminology, it would be a type of resonance machine.

The circuitry that develops high power in this device is really based on an existing but under-utilized power oscillator configuration, however, the ‘quantum’ part of the design has to do with how the generator is started. Conventional alternators (AC generators) usually have a device called an ‘exciter coil’. This coil is usually a smaller, separate rotor winding that provides an AC voltage that is rectified and used to power the generator’s field coil(s).

In the QEG, there is no internal, common exciter coil, and no rotor windings. In addition, to look at the circuit diagram, it is not apparent where the input power comes from to start resonance, and this is key; the QEG exciter coil is external to the generator, and the excitation signal is conducted through the quantum field (zero point) into the generator core, to start oscillation. Once the machine builds up to the resonant frequency, it powers itself (self running).”  – James M. Robitaille

Conclusion

Given the decades long propaganda campaign against free-energy , it will no doubt take some convincing to first prove to the public that harnessing cosmic or zero-point energy is possible, and then it will surely face a mainstream media blackout as well as persecution from government and industry.

Never-the-less, this is an exciting announcement and we challenge our readers to get the word out to help prove if this design is in fact what it claims to be.

Please have a look at the plans for the QEG, and pass them along to anyone who may be able to assist in the effort to verify and proliferate this technology.

Here is a video demonstration and explanation of the Quantum Energy Generator…

http://www.ultimatepowerfreedom.com/?aff_id=125 ... want to learn more click the video

About the Author

Terence Newton is a staff writer for WakingTimes.com, interested primarily with issues related to science, the human mind, and human consciousness.

Sources:

– http://www.fixtheworldproject.net/
– http://hopegirl2012.wordpress.com/
– http://www.bibliotecapleyades.net/tesla/esp_tesla_25.htm

This article is offered under Creative Commons license. It’s okay to republish it anywhere as long as attribution bio is included and all links remain intact.

~~ Help Waking Times to raise the vibration by sharing this article with the buttons below…

keep clean the planet and Space

Setting up Solar Panel Systems for Beginners

For many homesteaders, farmers and people who live off the grid an alternative power source is the perfect way to keep cost down. Wile still being able to provide the necessary power for special projects.

This set of videos was designed to help the person who is new to solar power get to know what goes into building one. The videos were created and posted by LDS Reliance.

The presenter describes in easy to understand terms how to set up a low power solar panel so that a beginner would be able to it for themselves. All of the information is presented in a way that makes it easier to follow and understand.

Benefits of watching the video DIY Project: Setting up Solar Panel Systems for Beginners

Learn the basics of setting up a small scale Solar power panel for your home.
The project describes everything that is necessary for you to have on hand in order to follow the video.
It also describes all of the steps you will need to follow to get from start to finish of the project.
The video is the perfect way for the presenter to get all of the information out to as many people as possible.

https://youtu.be/lB8q20QX6bA

https://youtu.be/A57woX3dUQU

https://youtu.be/UG2pbErPKi8

https://youtu.be/wU01ddBhauY

load then down and save .......

BY ·

Build a Hand Crank Generator From a Dishwasher Motor

Save the landfill and make something useful. Manual generators have been used to produce small amounts of emergency power for many years. You can find them on a number of things like weather radios and even electric lanterns. These are used extensively for people who live in areas that are commonly susceptible to severe weather and power outages. This DIY article was designed to introduce the reader to an easy to assemble hand crank generator.

This DIY Project was created, posted and shared with all of the readers at a website called Freedom Prepper. All the things that are needed can be easily found at almost any supply or hardware store. The information is presented in a way that makes it really easy to read and follow, but it could be useful to have a little bit of electrical skills. Learn about how easy it can be to repurpose an old dishwasher motor and turn it in a working generator. The project describes all of the needed materials, supplies and tools needed to get started and there is a video that includes a full instruction of how the system works.

https://youtu.be/n8mzi0u-rd8

the only way to learn is putting your hand and mind to work ...

By Mark Shwartz,

If you hadn’t heard, Asgardia just reached the end of its first election that saw rise to passionate debates, inspirational platforms and innovative solutions to some of the biggest problems facing the nation.

The final voting period of the election is now closed and we’re on the cusp of making history and putting together our first ever Parliament and while they may have been some bumps along the way and some valuable lessons learnt, we’ve achieved something truly amazing.

What’s next?

Now that all the votes are in there are still a few steps that will be required before our first parliament is fully formed and the process is expected to be concluded around the 31 ^st of March 2018 (06 April 0002).

Asgardia is taking the election process seriously and not only will the votes be counted by the Counting Commission , who will check the voting logfiles, but to further help ensure that all the votes that candidates have were gained fairly and legitimately, several independent companies have also been asked to analyse the votes.

Once each of the votes have been verified, candidates who met the requirements (including the mandatory donation) will be contacted individually and informed of their successful election and formally invited to an event in Vienna which will be the first meeting of Asgardian Parliament.

The event in Vienna is expected to be expenses paid to enable as many of the newly elected members of Parliament to attend as possible, and will be attended by both press and other prominent figures with an interest in the space nation.

Once this event (which is expected to last several days) has concluded we will have the first Asgardian Parliament and it will be time for them to return home and start getting to work on building the nation, picking a government and putting laws into place.

Got questions?

If you want to know more about the elections or the election process, drop an email to Citizens@Asgardia.space

We are the world , ! We are One !

"Our only chance to survive in the long term is to expand into space. The answers to these questions show that we have made great progress in the last hundred years, but if we want to continue beyond the next hundred years, the future is in space. That's why I'm in favor of space flights. "  Stephen Hawking

Life is a process that makes germinate within our hearts,

the seeds of Hope, Faith and Love. We never exterminate those seeds,

simply because we do not understand the critical moments of Life.
Who is the man who wants life, who wants many days to see good?
Because in you is the source of life, and in your light we can see the light

Less

The importance of having health and life insurance is  the benefits that we will achieve for the good of the Asgardians.   .more on the work we will do,    living in space or another planet,  will add  the best insurance health and life,  provides a unique service with all the benefits available. Both doctors, medical equipment, and much more. Pharmaceutics if we need it.  Also if an Asgardian Member  donates his / her body, a request will be entered where we will ask by writing and apply as a right by law that some services are included in the insurance for free. equally a low cost insurance for all. Asgardia Members,

This will be the beginning,

The important to learn about free energy,,,,     our plants,  the development of fruits,  and many food that is born from the earth, from the soil ... it is  great vital importance

Space food might conjure thoughts of the fruit-flavoured Tang drink, astronaut ice cream or space food sticks, but none of these products have the strong connection to space that one might imagine. Tang wasn’t developed for space, merely used during some early flights. Astronaut ice cream, the staple of air and space museums worldwide, was actually developed for spaceflight but hasn’t ever flown to space. And space food sticks were mostly a commercial product attempting to cash in on the excitement around spaceflight in the early 1960s, though they did fly aboard Skylab III.

Today’s space food eaten aboard the International Space Station (ISS) shares more similarities with military Meals Ready to Eat (MREs), vacuum sealed plastic pouches that must be rehydrated or reheated. Ideally, space food should be lightweight, compact in volume, nutritious, easy to prepare, eat and clean up (microgravity complicates all of these requirements), long lasting and delicious.

For a mission to Mars, food will need to last many years. Food for Mars-bound astronauts would be nearly two-and-half-years old by the time the astronauts returned to Earth, and supplies pre-positioned on Mars, sent during the launch window prior to a manned mission, would be three-and-a-half-years old by the time a crew arrived on Mars.

From a logistics view, the ideal food is a nutrient- and calorie-dense brick that would last for many years; the modern equivalent of hardtack and salt pork, though with better nutritional value. But such food ‘bricks’ are less than ideal from a crew perspective.

We were three of the six members of HI-SEAS Mission III, which gave us an insight into some of the issues that will be faced by future crews journeying to Mars.

HI-SEAS (Hawai’i Space Exploration Analog & Simulation) is a series of simulated Mars missions funded by NASA and run by Dr Kim Binsted of the University of Hawaii. The study’s overall goal is to investigate crew selection, performance and cohesion; and how to apply those lessons to a crewed mission to Mars.

Our mission, ran for eight months up to June 2015. During this time, we lived in a dome on the side of the Mauna Loa volcano in Hawaii, in the middle of a desolate lava field. We didn’t see people beyond the members of our crew and communication with the outside world was limited to methods with an imposed 20-minute delay to simulate the time it takes for a signal to travel between Earth and Mars.

Water was only periodically trucked in, thus limiting crew members to eight minutes of showering a week. Power was supplied by an off-grid energy system. And to venture outside we had to don simulated space suits. And for meals, we could only eat food cooked from shelf-stable ingredients – i.e. food that would last a three-year mission to Mars without spoiling.

Most of our meat, vegetables, fruit and dairy came in either dried or freeze-dried form. Removing the water delays spoilage and reduces weight and freeze-dried foods tend to have a Styrofoam-like texture before they’ve been rehydrated, while dried foods are much denser.

There was also a large stock of grains, legumes, flours, spices, seasonings and a variety of snacks. Generally, canned items were avoided because of their relatively heavy weight. Our pantry was a 20-foot shipping container mostly full of food – but even that wasn’t large enough to keep six people fed for the eight months. We needed three re-supplies as well.

Initially, we ate some of the pre-made freeze-dried meals similar to the kind used for camping, but they were disliked by most of the crew. A favourite low power meal was Build-Your-Own-Ramen – put all your favourite freeze dried veggies, meats, soup base and noodles in a big bowl and just add boiling water. On sunny days, when power wasn’t a concern, we were able to be more creative.

Social structure

As a crew, we decided how we wanted to organise our meals. For breakfast and lunch, people mostly cooked for themselves whereas dinner was prepared by a team of two and eaten all together. We set a rotating cooking schedule, which was occasionally interrupted by days of leftovers, low-power days or special celebration meals. Each day there was a chef in charge of making dinner with an assistant sous chef. There was also a clean-up crew of two for the day. After each chef and sous-chef had cooked, the sous chef would shift, so eventually every crew member worked with every other person in both a leading and following role. This was one of our few areas of social structure over the course of the mission and was devised by the crew. Other crews have organised their time and duties differently.

Our kitchen was small but well-equipped. We had induction cooktops, a small oven, microwave, toaster, kettle, rice cooker and yogurt maker. We also had a small garden which was Martha’s personal research project. It wasn’t large enough to make a significant contribution to our calories but the rare, small portions of fresh salad we got from it and the slightly more plentiful herbs were always a welcome addition. It was also a connection to ‘Earth’ and our only source of green.

Life in the HI-SEAS dome could become a little stale. The scenery through the one window never changed, the work was repetitive and the EVAs never took us more than a mile or two away.

The greatest source of variety day-to-day was our food though crew members quickly found out that cooking with the shelf-stable ingredients could be difficult and sometimes frustrating.

Challenges in the kitchen had to be overcome with willpower, creativity and necessity. Something that would take a few seconds on Earth, like adding cheese to a meal, might take a full hour on our simulated Mars because rehydrating the freeze-dried shredded cheese could only be done slowly and incrementally by adding cold water and keeping the container in the refrigerator.

The pre-made meal most commonly eaten in the dome was macaroni and cheese. Its popularity was more dependent on it being a staple comfort food; something that kept us all connected to our childhood, our days as college students and our ‘cheat days’ from whatever diet we were trying. Again, it tied us back to Earth.

Cooking for others was one of the ways that enabled us to come together as a crew. We celebrated the successes and laughed off the failures, and bonded much faster and deeper than in a traditional friendship.

Of all the challenges we faced as a crew, the daily meal we shared together consistently brought us closer together and kept us connected. It served as a gauge of morale; when a crewmate didn’t attend dinner, it was a signal to the rest of the crew that there was something wrong. Whether it was bad news from home, depression, isolation or just being in a good flow with your personal research, it gave the rest of the crew an indication to check in and keep better tabs on someone. If the social structure inside the dome became stressed, it was always most apparent during mealtimes when the normally jovial atmosphere became tense and quiet.

Expression of culture

Apart from nutrition, food affects us on so many levels; it’s hard to understate its importance on a mission. Not having enough food can cause low levels of blood sugar, make people irritable, resulting in low energy and lethargy. Not getting the right foods can affect mood, the body’s ability to function and repair itself, and to fend off illness.

Food is also an expression of culture and can connect you to a feeling of normalcy. Weekly debriefs were made pleasant by having our discussions over a batch of fresh scones and a pot of coffee. It’s also a creative endeavour and, by spending time creating something delicious for your crewmates, it becomes an expression of caring for them and fulfils the urge to do something nice for the people around you.

We ate well in the dome, and our best memories from those eight months involve special food that we made, but that doesn’t mean we weren’t excited when we got out and were able to eat all the things we’d been missing

Living in the confinements of the Dome, each day can seem very like the one before – you begin to lose a sense of time and the exact chronology of events becomes lost. But particularly good meals from the Dome still shine brightly in our memories. Stand-outs that we still talk about were special BBQ night, burger and multiple sushi and pizza nights. These meals were made even more special by witnessing the amount of time and effort each person put into making things as perfect as possible for the crew. Sophie recalls how proud she felt after spending an afternoon cooking and being able to present the crew with a splendid and delicious dinner.

Occasionally, the reality of space makes some of these activities and foods difficult. We didn’t have to deal with zero gravity, or even try to simulate that part of a mission to Mars. Living off-grid on renewable energy, however, we did have to deal with power shortages when the solar panels weren’t generating enough electricity to allow for cooking. We used to joke that when it’s cold and dark out, we can’t have heat or light – or a proper dinner.

One of the hardest parts of getting through dust storms, or patches of bad weather, was the inability to cook a regular meal. We had poor weather at Christmas, but decided to splurge on running the generator. We all felt it was important to have a festive holiday dinner with roast turkey, vegetables, stuffing and potatoes at a time when everyone on the crew would be missing their family and friends back home.

At a later point in the mission, we had a whole week of poor weather and lacked sufficient fuel for our back-up generators. That was a very cold, dark week where we had to get by on dried fruit and nuts, cereal and cereal bars, and other foods that didn’t require cooking. If we did heat water, we would coordinate with others so that we only had to run the kettle once or twice. Instant foods tend to be high in sodium, have a lot of wheat filler, and are generally not as tasty as what we could prepare ourselves. We were very happy when the sun started shining on us again and we could return to cooking.

Eating a freshly prepared, home-cooked meal every night and only cooking once a week was a luxurious arrangement. We ate well in the dome, and our best memories from those eight months involve special food that we made, though that doesn’t mean we weren’t excited when we got out and were able to eat all the things we’d been missing.

About the authors

Dr Martha Lenio runs Mars Green Consulting, a renewable energy and sustainability business in Ontario, Canada. In 2015 she commanded the third HI-SEAS mission, an eight-month simulation funded by NASA via the University of Hawaii at Manoa.

Sophie Milam, MEng, is a chemist and systems engineer for SVL Analytical Inc in Idaho, United States. She was Executive Officer for HI-SEAS mission III whilst also finishing her Master’s degree from the University of Idaho.

Zak Wilson was chief engineer of HI-SEAS mission III and is running a study titled ‘Remote Support of Additive Manufacturing on Martian Analogs’ during HI-SEAS mission V as a continuation of the 3D printing work he started during mission III.

References: https://room.eu.com/article/recipe-for-success-on-flights-to-mars

We going to explore more than we think...

15 exoplanets, orbiting red dwarf systems, have been certified by a group of researchers headed by Teruyuki Hirano of Tokyo Institute of Technology’s Department of Earth and Planetary Sciences. One of the brightest red dwarfs, K2-155 that is about 200 light years away from Earth, has three transiting super-Earths. Of those three super-Earths, the outermost planet, K2-155d, with a radius 1.6 times that of Earth, could be within the host star’s habitable zone.

The results were published in The Astronomical Journal , in two papers and are based on data from NASA Kepler spacecraft’s second mission, K2. They follow-up observations using ground-based telescopes, like the Subaru Telescope in Hawaii and the Nordic Optical Telescope (NOT) in Spain.

The researchers discovered that K2-155d could possibly hold liquid water on its surface based on three-dimensional global climate simulations. Hirano explained that in their simulations, the atmosphere and the composition of the planet were thought to be Earth-like, but there’s no guarantee that this is true.

In order to definitively conclude if K2-155d is habitable, a more precise estimate of the radius and temperature of the K2-155 star is  needed. In order to achieve such precision further studies are required. For instance, a study using interferometric techniques would help. However, an important outcome from the current studies was that planets orbiting red dwarfs may have remarkably similar characteristics to planets orbiting solar-type stars.

Hirano added that it’s crucial to note that the number of planets around red dwarfs is a lot smaller than the number around solar-type stars. Red dwarf systems, particularly coolest red dwarfs, are just starting to be investigated, so they are a very intriguing target for future exoplanet research.

For instance, while the so-called radius gap of planets around solar-type stars has been previously reported, this marks the first time that researchers have shown a similar gap in planets around red dwarfs.

Furthermore, the most likely explanation for the lack of large planets close to host stars is photoevaporation, which can strip away the envelope of the planetary atmosphere.

What’s more the researchers examined the relationship between planet radius and metallicity of the host star . Hirano stated that large planets are only found around metal-rich stars and what his team has found was consistent with their predictions. The few planets with a radius about three times that of Earth were found orbiting the most metal-rich red dwarfs.

The studies took place as part of the KESPRINT collaboration, a group made by the merger of KEST (Kepler Exoplanet Science Team) and ESPRINT (Equipo de Seguimiento de Planetas Rocosos Intepretando sus Transitos) in 2016.

With the planned launch of NASA’s Transiting Exoplanet Survey Satellite (TESS) in April 2018, Hirano is hopeful that even more planets will be discovered.

References: http://bit.ly/2p6VTVq

We Are The World

There comes a time
When we head a certain call
When the world must come together as one
There are people dying
And it's time to lend a hand to life
The greatest gift of all

We can't go on
Pretneding day by day
That someone, somewhere will soon make a change
We are all a part of
God's great big family
And the truth, you know love is all we need

[Chorus]
We are the world
We are the  Humans
We are the ones who make a brighter day
So let's start giving
There's a choice we're making
We're saving our own lives
It's true we'll make a better day
Just you and me

Send them your heart
So they'll know that someone cares
And their lives will be stronger and free
As God has shown us by turning stone to bread
So we all must lend a helping hand

[Chorus]
We are the world
We are the Humans
We are the ones who make a brighter day
So let's start giving
There's a choice we're making
We're saving our own lives
It's true we'll make a better day
Just you and me

When you're down and out
There seems no hope at all
But if you just believe
There's no way we can fall
Well, well, well, well, let us realize
That a change will only come
When we stand together as one

[Chorus]
We are the world
We are the Humans
We are the ones who make a brighter day
So let's start giving
There's a choice we're making
We're saving our own lives
It's true we'll make a better day
Just you and me

Insurance is Coming to the Blockchain Through SuchApp and WishKnish

SuchApp and WishKnish are partnering up to be the first to introduce an insurance marketplace that uses the blockchain. This partnership will see SuchApp – the innovative blockchain-powered messaging platform – and WishKnish – the decentralized network of gamified, coin-agnostic, social marketplaces – joining forces to co-develop a decentralized business ecosystem that enables insurance management to be more efficient for both insurers and customers.

Ronny Shany, CEO of SuchApp and co-founder of HighTV stated that the global insurance market is expanding by leaps and bounds in both developed and developing markets. The global insurance premium is presently worth over $5 trillion USD, and while premiums and insurance capital are rising, so is the demand for better customer service. Thus, their goal at SuchApp is to craft a global insurance marketplace that increases customer service and communication between clients and adjusters, while implementing the features of WishKnish as a way to offer a secure and convenient marketplace that is advantageous for  both the business and the customer.

SuchApp’s 5G blockchain-enabled real time messaging platform allows businesses to engage with customers. With SuchApp taking the first step into the global insurance market, the company plans to expand upon their current business model by designing an easy-to-use platform where:

• Customers can buy insurance policies through SuchApp’s SPS Token, a digital currency operating on the ERC20 protocol.
• Customers and insurance companies can manage policies instantly over the SuchApp platform.
• Insurance adjusters can use SuchApp to create customer service groups to address claims and any other important issues.
• Location-based messaging that gives insurance companies the chance to focus particularly on local markets.

Alisa Gus, the CEO of WishKnish expressed how proud and excited they are to see their technology being used to advance mainstream blockchain adoption. By offering a secure, decentralized platform that expands transparency and is protected against failure and tampering, they are able to leverage blockchain technology to make sure customers and insurance companies are better protected against fraud.

Insurance companies using the two companies’ platforms get access to all of their combined feature sets, such as SuchApp’s innovative personal and group VOIP conferences and WishKnish’s marketing and promotional tools, in addition to SuchApp’s fully functional loyalty programs. All correspondence over SuchApp’s platform is 100 percent encrypted, which means that sensitive information is protected against outside threats, while WishKnish Storefront technology makes sure that customers can be incentivized towards behaviors and actions that are advantageous to them and their community and payments are handled in a coin-agnostic manner.

SuchApp’s goal is to corner a part of the global insurance market that is looking to insurtech companies that are challenging the way typical insurance businesses function. WishKnish continues to expand its global businesses in retail commerce and Blockchain As A Services (BaaS) to bring their customized Blockchain solutions to corporate and Government clients.

For this partnership, the two companies plan to solidify their position as a multi-faceted business tool that permits insurance companies to stay connected with customers, design marketing campaigns, and grow their customer base.

References: http://prn.to/2Cl3iJL

In the first Parliament job is to form the best insurance with all the power laws, rules , amendments , and the right to be reform for better privilege,  to all Senior a insurance of your choice, all right,   Power of attorney, a friend, family, ...etc..

The right not to be discriminated against , the right to vote

Right to explore the kingdom , maybe a transport system of planets.

Senior can contribute their talents as part of Art, Architecture, Medical, Science, Teachers, work in the Government, Court, Secretary, meal, Photography, engineers and environmental, water, plants, Animals, and much other ect ect.   Seniors have the rights to different religions faiths and culture,

We will work at the same time with. The Power world of free energy     for a better planet also  space... . free lights for inside vegetations, plants,  and more ...all that can be invented with the best functions with free energy...stop air pollution.

We always need each other .work as One..   for knowledge of those times and what will be found in the unknown ...the best Nacion in Space and earth...

See the universe, and travel to the unknown, a new live is around the corner...

The fascinating “free energy” technologies shown in the video in this article will show you the power of free energy and how free energy will make crude oil, coal, and nuclear energy irrelevant in the near future.

One of the free energy technologies is able to convert light and infrared energy into electricity that can be used to power homes and businesses. This technology utilizes the power of nanotechnology and is a lot more efficient than conventional solar panels.

Another free energy technology shown in the video below can be used to store energy without the need of batteries. It stores energy by using a special nanomaterial that has the ability to “park” electrons and release them as energy when needed.

For more interesting information about free energy technology, read these two articles titled Five “Free Energy” Devices that Could Save You Thousands of Dollars and World’s First Self Powered Silicon Crystal Graphite Powercells . https://youtu.be/ghhgUmGBjX8

The Future of Free Energy is Here Now! The End of Oil, Coal and Nuclear Pollution