Welcome to BrainChanger Face Reading. You can read the features of your face and understand your personality. These are the notes that were taken on 500 faces in our office.Just look straight into the mirror and read these nine attributes of your character. Eyes - worldview Shape across bottom lid - openness Straight - wary Curved - open Depth - assertiveness Deepset - laid back and waiting Protruding - reactive and dominating Width - focus Close set - detail oriented Far set - trend setter Eyelids - intimacy Thick - likes intimacy Thin - prefers detachment Eyebrows - thinking Thickness - thinking quality Uniformly thick - powerful thinker Thick at beginning - great starter Thick at end - great finisher Thin - fewer ideas Hairs - ideas Contradictory - given to conflict Scattered - disconnected thinking Root hairs - early bloomer Across - constant thinking, insomnia Shape - orientation Curved - people Straight - ideas Angular - conflict Height - patience High above eyes - patient Low above eyes - impulsive Ears - learning Size - listening Large - listening to people Small - listening to self Position - speed High - quick learner Low - careful learner Flare - conformity Stickout - rebel Close - conformist Nose - ambition Tip - money consciousness Large - schemer and planner Small - uninterested in money Turned down - shrewd Turned up - impetuous Nostrils - spending Large - spender Small - tightwad Roots - family connection Ample - family support Lacking - social detachment Length - career Long - leads others to work Short - hard worker Shape - work style Straight - logic Hump - creativity Swayed - intuition Padding - people Padded - need people Unpadded - loner Cheeks - leadership Bones - fame Prominent - bold Small - private Pads - recruitment Heavy - draws followers Light - works alone Width - courage Wide set - confident Close set - steady Shape - personality Large cheeks - leadership Tapering toward chin - passion Expanding toward jaws - peacemaker Flat cheeks - polite Jaws - stamina Large - physically strong Small - delicate constitution Chin - willpower Size - aggression Large - demanding Small - compliant Width - survival Wide - tough Narrow - tender Shape - battles Curved - people Straight - ideas Angular - control Mouth - expression Size - fun Large - social Small - sincere Upper lip - expression of thought Thick - outspoken Thin - secretive Lower lip - expression of emotion Thick - persuader Thin - reserved Teeth - decisions Even - poised Gaps - joker Big front teeth - stubborn Small front teeth - selfless Crooked - conflicted Buck - shy Underbite - aggressive Angles - interpretation Eyes - life view Angle down - pessimist Straight - realist Angle up - optimist Mouth - spoken philosophy Angle down - pessimist Straight - realist Angle up - optimist Areas - priorities Forehead - thinking Largest of three - intellectual Smallest of three - nonacademic Nose - ambition Largest of three - driven Smallest of three - content Mouth-sensuality Largest of three - earthy Smallest of three - nonphysical

Top 6 Psychology websites 0

Top 6 Psychology websites

After a great research on the internet about Psychology websites. I found these wonderful top psychology websites. These websites definitely useful for one who wants to learn psychology.

A list of top psychology websites

List of websites 1 to 3

1. PsychTronics: Psychtronics.com is the world’s leading Psychology website which contains all interesting topics about psychology and you need not to be a professional to understand the articles in psychtronics they are easy to understand to college students and one who loves psychology and want to learn psychology.

                 My suggestion is to follow psychtronics because all the articles in psychtronics are written by the professors and professionals of psychology universities.

2.Wikipedia

Wikipedia, the largest, free, multi-lingual encyclopedia on the web has great informative articles on a variety of subjects in psychology. From the history of psychology and methods of psychological research to its numerous sub-fields of study, Wikipedia is a continuously updated treasure trove of knowledge.
Each page you navigate to has a wealth of resources from people to publications, all organized in a structured fashion unique to Wikipedia.

3. WebMD Mental Health

WebMD’s Mental Health section has exhaustive information on disorders and treatment. It features Guide sections for specific disorders, with informative slideshows, latest news, and articles. All this is backed by the popular community section featuring blogs and message boards.

Cendrawasih Motorbike Is Powered by Palm Oil 0

The price of most commodities has reached its peak, so does the rate of petrol. In such a case, people are trying to look for an alternative source of energy when it comes to using motor vehicles. The result of the search has been fruitful. Powered by palm oil, this Cendrawasih Bike is equipped with the necessary racing kit. The design, inspired by the shape of Cenderawasih, a bird of paradise. With a stunning and aggressive looks, this bike is sure to please many rocket heads.

Designer : Imran Othman

different kinds of robos 0

There are numerous ways how to define types of robots. As I have seen the possible divisions varies widely. The main reason of these differences is that different scholars tend to have different views on issues that should be taught under term "robotics".

For example - most scholars that teach robotics usually focus mainly on industrial robots, neglecting service robots completely. Therefore when talking about types of robots they usually talk about types of industrial robots. There is a strong reason for this though - the vast majority of robotics engineers will have to deal mostly with industrial robotics.
Nevertheless, industrial robots are not the only ones. Therefore when dividing robots into types this division should be broad enough to include everything that can be understood as a robot.
There are two possible ways how this could be done. First, you can divide robots into types by their application and second - by the way they move (or doesn't). I acknowledge that there are other possible ways how to define various types of robots but in my opinion these two are the most relevant ones. Also, I prefer to use both these classifications together. This way two questions about a robot would be already answered - "What it does?" and "How it does its job?"

Types of robots by application

Nowadays, robots do a lot of different tasks in many fields. And this number of jobs entrusted to robots is growing steadily. That's why one of the best ways how to divide robots into types is a division by their application.There are:

*Industrial robots

*Domestic or household robots

*Medical robots

*Service robots
*Military robots

*Entertainment robots

*Exploration robots
Now, as you can see there are examples that fit into more than one of these types. For example, there can be a deep see exploration robot that can gather some valuable information that can be used for military purposes.
Also, I have seen that a division into two types is used, accordingly - industrial and service robots. However, I can not see how a Mars exploration rover fits into one of these general types. Therefore I have used "service robots" in a narrower manner. In my version a term "service robots" serves as "others". This is basically a type where robots that don't fit into other types should fall in.

Types of robots by locomotion and kinematics

As you can understand, robot's application alone does not provide enough information when talking about a specific robot. For example an industrial robot - usually, when talking about industrial robots we think of stationary robots in a work cell that do a specific task. That's alright, but if there is an AVG (Automated Guided Vehicle) in a factory? It is also a robotic device working in an industrial environment. So, I propose to use both of these classifications together.
So there are:
1. Stationary robots (including robotic arms with a global axis of movement)

1.1 Cartesian/Gantry robots

1.2 Cylindrical robots

1.3 Spherical robots
1.4 SCARA robots
1.5 Articulated robots (robotic arms)
1.6 Parallel robots


2. Wheeled robots
2.1 Single wheel (ball) robots
2.2 Two-wheeled robots
2.3 Three and more wheel robots


3. Legged robots
3.1 Bipedal robots (humanoid robots)
3.2 Tripedal robots
3.3 quadrupedal robots
3.4 hexapod robots
3.5 other numbers of legs


4. Swimming robots
5. Flying robots
6. Mobile spherical robots (robotic balls)
7. Others
Wondering about others? Yes, there are others. For example snake-like robots. There are many fields of research that deal with different innovative types of robots. Someday they will be very useful. However, by now I'll put them under the "others" type.
Of course, nothing of this is carved in stone, especially in a field of robotics where everything changes almost monthly nowadays. Still, in my opinion these types of classification do their job well enough.

As you may have noticed, I use the classification by application as the main outline of this site. I hope I managed to give you some insight on ways how to define various types of robots.

Helmet Niqab by Death Spray Custom 0

Helmet, the life saving guard was invented for its due purpose of protecting the head from injuries. Helmets used for various purposes have different designs. While designers create different types of helmets that meets its intended purpose, helmets designed by Death Spray are quite unusual, however, meets the requirement of the users. Death Spray always tries to be innovative in design when compared to other designers and it reflects well in its new creation, Helmet Niqab. This stylish piece of work is as traditional as other helmets with a variation in its aesthetics and is designed to fit accurately. It conceals the entire head, leaving a portion open for the eyes. This model meets sinister and futuristic needs of the users. Helmet Niqab looks creepy in its appearance; however, its cutting-edge design by Death Spray is sure to hit the shelves.

Designer : Death Spray Custom

types of robots 2

Robots can be found in the manufacturing industry, the military, space exploration, transportation, and medical applications. Below are just some of the uses for robots.

Robots on Earth

Typical industrial robots do jobs that are difficult, dangerous or dull. They lift heavy objects, paint, handle chemicals, and perform assembly work. They perform the same job hour after hour, day after day with precision. They don't get tired and they don't make errors associated with fatigue and so are ideally suited to performing repetitive tasks. The major categories of industrial robots by mechanical structure are:

• Cartesian robot /Gantry robot: Used for pick and place work, application of sealant, assembly operations, handling machine tools and arc welding. It's a robot whose arm has three prismatic joints, whose axes are coincident with a Cartesian coordinator.
• Cylindrical robot: Used for assembly operations, handling at machine tools, spot welding, and handling at diecasting machines. It's a robot whose axes form a cylindrical coordinate system.
• Spherical/Polar robot: Used for handling at machine tools, spot welding, diecasting, fettling machines, gas welding and arc welding. It's a robot whose axes form a polar coordinate system.
• SCARA robot: Used for pick and place work, application of sealant, assembly operations and handling machine tools. It's a robot which has two parallel rotary joints to provide compliance in a plane.
• Articulated robot: Used for assembly operations, diecasting, fettling machines, gas welding, arc welding and spray painting. It's a robot whose arm has at least three rotary joints.
• Parallel robot: One use is a mobile platform handling cockpit flight simulators. It's a robot whose arms have concurrent prismatic or rotary joints.

Industrial robots are found in a variety of locations including the automobile and manufacturing industries. Robots cut and shape fabricated parts, assemble machinery and inspect manufactured parts. Some types of jobs robots do: load bricks, die cast, drill, fasten, forge, make glass, grind, heat treat, load/unload machines, machine parts, handle parts, measure, monitor radiation, run nuts, sort parts, clean parts, profile objects, perform quality control, rivet, sand blast, change tools and weld.
Outside the manufacturing world robots perform other important jobs. They can be found in hazardous duty service, CAD/CAM design and prototyping, maintenance jobs, fighting fires, medical applications, military warfare and on the farm.
Farmers drive over a billion slooooww tractor miles every year on the same ground. Their land is generally gentle, and proven robot navigation techniques can be applied to this environment. A robot agricultural harvester named Demeter is a model for commercializing mobile robotics technology. The Demeter harvester contains controllers, positioners, safeguards, and task software specialized to the needs commercial agriculture.
Some robots are used to investigate hazardous and dangerous environments. The Pioneer robot is a remote reconnaissance system for structural analysis of the Chornobyl Unit 4 reactor building. Its major components are a teleoperated mobile robot for deploying sensor and sampling payloads, a mapper for creating photorealistic 3D models of the building interior, a coreborer for cutting and retrieving samples of structural materials, and a suite of radiation and other environmental sensors.
An eight-legged, tethered, robot named Dante II descended into the active crater of Mt. Spurr, an Alaskan volcano 90 miles west of Anchorage. Dante II's mission was to rappel and walk autonomously over rough terrain in a harsh environment; receive instructions from remote operators; demonstrate sophisticated communications and control software; and determine how much carbon dioxide, hydrogen sulfide, and sulfur dioxide exist in the steamy gas emanating from fumaroles in the crater. Via satellite, Dante II sent back visual information and other data, as well as received instruction from human operators at control stations in Anchorage, Washington D.C., and the NASA Ames Research Center near San Francisco. Dante II saves volcanologists from having to enter the craters of active volcanoes. It also demonstrates the technology necessary for a robot to explore the surface of the moon or planets. That is, the robot must be able to walk on rough terrain in a harsh environment, receive instructions from remote operators about where to go next, and reach those commanded goals autonomously.

Robotic underwater rovers are used explore and gather information about many facets of our marine environment. One example of underwater exploration isProject Jeremy, a collaboration between NASA and Santa Clara University. Scientists sent an underwater telepresence remotely operated vehicle (TROV) into the freezing Arctic Ocean waters to investigate the remains of a whaling fleet lost in 1871. The TROV was tethered to the surface boat Polar Star by a cable that carried power and instructions down to the robot and the robot returned video images up to the Polar Star. The TROV located two ships which it documented using stereoscopic video cameras and control mechanisms like the ones on the Mars Pathfinder. In addition to pictures, the TROV can also collect artifacts and gather information about the water conditions. By learning how to study extreme environments on earth, scientists will be better prepared to study environments on other planets.

Check out Ways to Use Robots

Robots in Space

Space-based robotic technology at NASA falls within three specific mission areas: exploration robotics, science payload maintenance, and on-orbit servicing. Related elements are terrestrial/commercial applications which transfer technologies generated from space telerobotics to the commercial sector and component technology which encompasses the development of joint designs, muscle wire, exoskeletons and sensor technology.Today, two important devices exist which are proven space robots. One is the Remotely Operated Vehicle (ROV) and the other is the Remote Manipulator System (RMS). An ROV can be an unmanned spacecraft that remains in flight, a lander that makes contact with an extraterrestrial body and operates from a stationary position, or a rover that can move over terrain once it has landed. It is difficult to say exactly when early spacecraft evolved from simple automatons to robot explorers or ROVs. Even the earliest and simplest spacecraft operated with some preprogrammed functions monitored closely from Earth. One of the best known ROV's is the Sojourner rover that was deployed by the Mars Pathfinder spacecraft. Several NASA centers are involved in developing planetary explorers and space-based robots.
The most common type of existing robotic device is the robot arm often used in industry and manufacturing. The mechanical arm recreates many of the movements of the human arm, having not only side-to-side and up-and-down motion, but also a full 360-degree circular motion at the wrist, which humans do not have. Robot arms are of two types. One is computer-operated and programmed for a specific function. The other requires a human to actually control the strength and movement of the arm to perform the task. To date, the NASA Remote Manipulator System (RMS) robot arm has performed a number of tasks on many space missions-serving as a grappler, a remote assembly device, and also as a positioning and anchoring device for astronauts working in space.
Check out Ways to Use Robots

NEOS Motorbike And Modular Sidecar System Enhances Future Transportation Efficiency 0

Efficiency of a product is the ability to perform more than one task and when it’s a motorbike that can act as a modular sidecar, surely the outcome is something exceptional.

NEOS transportation concept has been designed for the 21st century combining the facility of a motorbike along with a modular sidecar system that features a lot of safety features, while offering enhanced essence of thrill and adventure, making it a vehicle far beyond imagination. Having an extraordinary appearance and unparallel functionality, this motorbike is able to perfectly suit in the future streets. The entire system consists of a single seater motorbike, a sidecar and storage attachment and a docking system for the sidecar pod. The vehicle includes an airbag deployment system and a safety cell for enhanced protection of the driver, while giving superior functionality for personal daily commute in the busy future street. When required an additional seating or a storage compartment, the sidecar pod can easily be attached with the motorbike for added user experience and convenience.

Designer : Daniel Munnink

Band In Your Pocket Cell Phone Can Transform You Voice Into 5 Different Musical Instruments 0

If someone is claiming in the phone that he or she can play 5 musical instruments with great expertise, before getting amazed of his or her stunning abilities, make sure he or she doesn’t own a Band in Your Pocket cell phone.

Band in Your Pocket is a cell phone concept that has the technology to transform your voice into 5 different instruments through different attachments. This innovative tool is something you must admire as a way of expressing your feelings and emotions in a more intuitive way. The device comprises superb textures and attractive finishes that ensure enhanced aesthetics along with unique functionality. You can watch the video here: http://www.youtube.com/watch?v=0yvas9xKCeI

Designer : Marianne Bailey

ZigZag Three Wheeled Personal Electric Vehicle 0

Do you still remember your great great grandpa bicycle? This personal electric vehicle is inspired from those classic high wheel bicycles. ZigZag three wheeled electric vehicle tries to answer the need for environmentally friendly transportation. The frame is made of aluminum alloy 6161 which is commonly used to produce lightweight products. The designers hope that this vehicle can satisfy the need of compact, functional, easy to use, and fun transportation for the future.

The users of my product would be initially people 15-40 years old, or people that need to use this product on for work to arrive fast and secure. Thanks to the innovative design, ZigZag can be adapted according the measures of the user, the seat, footrest and handlebar can be regulated in angle and height. The product life cycle can be helped by the idea that can be adapted and added for other products or needs because it can be modified for the user’s needs.

Designer : Daniel Castillo B. and Camilo Parra P.

Collapsible Bicycle by Kevin Scott 0

It’s not often that I could see such a revolutionary design yet it is not just a concept. This bike design from Kevin Scott is a bendable bicycle that you can literally wrap around a lamp post or a pole. It certainly will stop thieves from targeting your bike. The young Industrial Designer used a ratchet system built into the frame of the bike to make it possible to wrap the bike around a pole. The bike bends to lock onto itself, there’s no need for a chain, a regular bike lock will be able to secure the frame and both wheels. His main objective was not just to secure all bike’s components within the lock, but also to allow the bike to be stored in small spaces. A very cool bike design, indeed!
Designer : Kevin Scott

Kevin said: “This has validated how I feel about the product. It’s a justification of the uniqueness of the design and the possibilities for taking it further. I intend to use the prize money to outsource production of some of the key components to allow for full testing.
“I am now going to take this forward to produce a fully resolved solution and hopefully this will be a stepping stone into a career in the bike designing industry.”