Introduction to quantum mechanics Click to see animation.
The math is a way of describing things that happen in the real world. You might imagine that it would be easy to get both the exact position of something and its exact mass, path, and speed at the same time.
However, in reality you have to do two things to get Werner heisenberg answer. If you are measuring the position and momentum of Werner heisenberg bullet that is stuck in a cliff of a great mountain somewhere, it is a simple matter.
The mountain does not appear to be going anywhere, and neither is the bullet. So its position is known and its velocity is 0, so its momentum is also 0. But if the bullet is somewhere between a gun and a target, it will be difficult to get its position at any given time.
The best we may be able to do is to take its picture using a camera with a very fast shutter. But a single squeeze of the shutter would give you only one thing, the bullet's position at time t.
To get the momentum we might put a block of paraffin in the bullet's way and measure how the block of paraffin moved when it stopped the bullet.
Or, if we knew the bullet's mass, we might take a sequence of two pictures, compute the velocity by knowing the difference between the two positions of the bullet and the time between its two appearances. However we do it, we need to measure mass and position and time between appearances.
We end up making at least two measurements to get to x and p. In that case we have to choose which measurement to make first, and which to make second. It seems to make no difference which order our measurements are made in.
Measuring the bullet's mass and then measuring its positions twice, or measuring the bullet's positions twice and then recovering the bullet and measuring its mass would not make any difference, would it? After all, we have not done anything to the bullet when we weigh it or when we make photographs of it.
On the very small scale when we are measuring something like an electron, however, each measurement does something to it. If we measure position first, then we change its momemtum in the process.
If we measure the electron's momentum first, then we change its position in the process.
Our hope would be to measure one of them and then measure the other before anything changed, but our measuring itself makes a change, and the best we can hope to do is to reduce to a minimum the energy we contribute to the electron by measuring it.
That minimum amount of energy has the Planck constant as one of its factors. Uncertainty goes beyond matrix math[ change change source ] Heisenberg's uncertainty principle was found in the earliest equations of the "new" quantum physics, and the theory was given by using matrix math. Indeterminacy in nature, not uncertainty of humans[ change change source ] There have been two very different ways of looking at what Heisenberg discovered:Werner Heisenberg's high school years were interrupted by World War I, when he had to leave school to help harvest crops in Bavaria.
Back in Munich after the war, he volunteered as a messenger for. Werner Heisenberg was born in and died in He was four years old when Einstein formulated special relativity in Ten years later, when he was in high school, Heisenberg became interested in Einstein's theory and started his physics career out of his respect for Einstein.
Today the name Werner Heisenberg means little, even to highly educated people. But on the eve of World War II, he was a Nobel laureate with a reputation as possibly the world’s greatest atomic physicist.
So when the community of physicists realized that an atomic bomb was theoretically possible. German physicist Werner Heisenberg was a leader in physics, winning the Nobel Prize in Physics for his discovery of the uncertainty principle, which states that it is impossible to specify the exact position and momentum of a particle (tiny piece of matter) at the same time.
Werner Heisenberg was a German physicist and philosopher who is noted for his crucial contributions to quantum mechanics.
He devised a method to formulate. Werner Heisenberg on Quantum Mechanics. The Wave Structure of Matter (WSM) explains Werner Heisenberg Uncertainty Principle as caused by Quantum Physics / Mechanics incorrect 'particle' conception of Matter.
Werner Heisenberg Biography, Pictures, Quotes on absurdities of Quantum Physics.