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Covariance and Contravariance in Physics

Covariance and Contravariance in Physics. Brian Beckman Micrsosoft 13 Oct 2009. Covariance and Contravariance. Show up in math, physics, and programming Different ideas with the same name? Or facets of one bigger idea? What's the common thread? Seem to be slippery concepts

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Covariance and Contravariance in Physics

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  1. Covariance and Contravariance in Physics Brian Beckman Micrsosoft 13 Oct 2009

  2. Covariance and Contravariance • Show up in math, physics, and programming • Different ideas with the same name? • Or facets of one bigger idea? • What's the common thread? • Seem to be slippery concepts • you think you've got it, then *smack* something goes backwards • Why? Can we fix that?

  3. Start with the "Devil I Know" • Explore these concepts in physics context • Later, tie them into similar concepts in programming (and maybe other math areas)

  4. Ok, What are They in Physics? • They arise from application of "Differential Geometry on Manifolds" • Foundation for General Relativity • GPS, Astrometry, Cosmology, Black holes, ... • Most other areas of physics have been Geometricized • Mechanics, Electrodynamics, Quantum physics, Statistical physics, ... • Looks like String Theory or Loop Quantum Gravity will "seal the deal" • We think all of physics will be Geometricized

  5. Analyze the Words • "Co- and Contra-" imply duality • They go together • "Variance" implies movement • They show up when something changes

  6. A Running Example • Imagine a flight plan from Reykjavik to Johannesburg • Imagine two functions: • Waypoint as a function of time • Fuel as a function of waypoint

  7. Two Functions Call this FLIGHT PATH Call this FUEL • Give it a real-number time t, it gives you a location or point • Give it a point, it gives you a real-number fuel-spent value

  8. Composition: fuel over time • – give it a time, you get a fuel-spent • What's the fuel burn-rate? • In 19th-century notation, plus “chain rule” • Great, but what are and ? • Can’t compute them without coordinates …

  9. Relate fuel & path to coordinates • Let x be a coordinate function, that gives to every point p on the globe a lat, lon, alt • Define a new function that delivers fuel-spent as a function of coordinates x • Use associative law • Rename (because we will never again separate x from p • Our new fuel-over-time function

  10. Now compute fuel burn-rate • Still sticking with "picturesque" 19th-century notation: • You may recognize this as • The burn rate is a gradient times a velocity • The notation is broken, but before fixing it...

  11. Here's the Big Idea • The answer CAN'T depend on the choice of coordinate system • The anser MUST be invariant w.r.t. changes in coordinates • We can get this if one of the two factors is covariant and the other is contravariant w.r.t. coordinate change, but which is which?

  12. Intuition by Example • Let • Coordinates are numbers relating to geometry • When xis 1, y is a, bigger than x • y is a finer-grained coordinate system • It takes more y's than x's to get from one point to another

  13. Gradients are Covariant • The change in f for a unit change in y must therefore be smaller than the change in f for a unit change in x • Check this with the good-ol' chain rule again • When a>1, df/dy is smaller than df/dx • when the coordinate spacing is smaller, the changes in f are smaller • The gradient co-varies with the coordinate spacing

  14. Velocities are Contravariant • Chain rule again • When the coordinate spacing gets smaller, the velocity vector must cover more coordinates to represent the same velocity, so its numbers get bigger • The velocity varies contra to (against) the coordinate spacing

  15. Intuition versus Precision • That demonstration gives the intuition and the mnemonic • The chain rule gives the precise answer • In any number of dimensions • For any differentiable coordinate changes • non-linear, curved, twisted, ... • with many kinds of singularities • this is where many interesting details go…

  16. The Notation is Broken • What is a derivative? • It's the best linear approximation to a function at a certain point • Linear approximation means you give it a change in inputs to the original function, it gives the approximate change in the output of the original function • The derivative is thus a function from points to linear approximations • The derivative operator converts a function of points to a function of points

  17. Notation is Broken (cont...) • With all that in mind, what could mean? • This must be a function of time t that produces a linear approximation to • Let's write it like this • as an equality on linear approximations!

  18. The Better Notation • is linear approx to at • is linear approx to at • is linear approx to at

  19. Now Change Coordinates

  20. And Here They Are • Here's the covariant buddy, the gradient • Here's the contravariant buddy, the velocity • This is just the beginning... • But the end for now!

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