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Basic Mathematics Rende Steerenberg BE/OP CERN Accelerator School Basic Accelerator Science & Technology at CERN 3 – 7 February 2014 – Chavannes de Bogis.

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Presentation on theme: "Basic Mathematics Rende Steerenberg BE/OP CERN Accelerator School Basic Accelerator Science & Technology at CERN 3 – 7 February 2014 – Chavannes de Bogis."— Presentation transcript:

1 Basic Mathematics Rende Steerenberg BE/OP CERN Accelerator School Basic Accelerator Science & Technology at CERN 3 – 7 February 2014 – Chavannes de Bogis

2 Basics of Accelerator Science & Technology at CERN Contents Vectors & Matrices Differential Equations Some Units we use CAS - 3 February 2014 - Chavannes de Bogis2Rende Steerenberg (BE/OP)

3 Basics of Accelerator Science & Technology at CERN Contents Vectors & Matrices Differential Equations Some Units we use CAS - 3 February 2014 - Chavannes de Bogis3Rende Steerenberg (BE/OP)

4 Basics of Accelerator Science & Technology at CERN Scalars & Vectors Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis4 Scalar, a single quantity or value Vector, (origin,) length, direction

5 Basics of Accelerator Science & Technology at CERN Coordinate systems Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis5 (x,y) Cartesian coordinates r is the length of the vector y x r  θ gives the direction of the vector (r,  ) Polar coordinates r A vector has 2 or more quantities associated with it

6 Basics of Accelerator Science & Technology at CERN Vector Cross Product Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis6 θ b a a × b The cross product a × b is defined by: Direction: a × b is perpendicular (normal) on the plane through a and b The length of a × b is the surface of the parallelogram formed by a and b a and b are two vectors in the in a plane separated by angle θ

7 Basics of Accelerator Science & Technology at CERN Cross Product & Magnetic Field Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis7 Force B field Direction of current The Lorentz force is a pure magnetic field The reason why our particles move around our “circular” machines under the influence of the magnetic fields “E.M. fields” by Werner Herr “Transverse Beam Dynamics” by Bernhard Holzer This afternoon Tuesday

8 Basics of Accelerator Science & Technology at CERN A Rotating Coordinate System Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis8 It travels on the central orbit Vertical Horizontal Longitudinal y s or z x 

9 Basics of Accelerator Science & Technology at CERN To move from one point (A) to any other point (B) one needs control of both Length and Direction. Moving a Point Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis9 Rather clumsy ! Is there a more efficient way of doing this ? 2 equations needed !!! y x A B

10 Basics of Accelerator Science & Technology at CERN Matrices & Vectors Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis10 So, we have: Rows Columns Lets write this as one equation: A and B are Vectors or Matrices A and B have 2 rows and 1 column M is a Matrix and has 2 rows and 2 columns

11 Basics of Accelerator Science & Technology at CERN Matrix Multiplication Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis11 This matrix multiplication results in: Equals This implies: This defines the rules for matrix multiplication Is this really simpler ?

12 Basics of Accelerator Science & Technology at CERN Moving a point & Matrices Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis12 x y x1 x3 x2 y3 y2 y1 1 3 2 Lets apply what we just learned and move a point around: M1 transforms 1 to 2 M2 transforms 2 to 3 This defines M3=M2M1

13 Basics of Accelerator Science & Technology at CERN Matrices & Accelerators Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis13 We use matrices to describe the various magnetic elements in our accelerator. The x and y co-ordinates are the position and angle of each individual particle. If we know the position and angle of any particle at one point, then to calculate its position and angle at another point we multiply all the matrices describing the magnetic elements between the two points to give a single matrix Now we are able to calculate the final co-ordinates for any initial pair of particle co-ordinates, provided all the element matrices are known. See Bernhard Holzer’s lectures

14 Basics of Accelerator Science & Technology at CERN The Unit Matrix Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis14 X new = X old Y new = Y old There is a special matrix that when multiplied with an initial point will result in the same final point. The result is : The Unit matrix has no effect on x and y

15 Basics of Accelerator Science & Technology at CERN Going backwards Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis15 What about going back from a final point to the corresponding initial point ? or For the reverse we need another matrix M -1 The combination of M and M -1 does have no effect M -1 is the “inverse” or “reciprocal” matrix of M. such that

16 Basics of Accelerator Science & Technology at CERN Calculating the Inverse Matrix Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis16 If we have a 2 x 2 matrix: Then the inverse matrix is calculated by: The term (ad – bc) is called the determinate, which is just a number (scalar).

17 Basics of Accelerator Science & Technology at CERN A Practical Example Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis17 or Changing the current in two sets of quadrupole magnets (F & D) changes the horizontal and vertical tunes (Q h & Q v ). This can be expressed by the following matrix relationship: Change I F then I D and measure the changes in Q h and Q v Calculate the matrix M Calculate the inverse matrix M -1 Use now M -1 to calculate the current changes ( Δ I F and Δ I D ) needed for any required change in tune ( Δ Q h and Δ Q v ).

18 Basics of Accelerator Science & Technology at CERN Contents Vectors & Matrices Differential Equations Some Units we use CAS - 3 February 2014 - Chavannes de Bogis18Rende Steerenberg (BE/OP)

19 Basics of Accelerator Science & Technology at CERN The Pendulum Lets use a pendulum as example The length of the pendulum is L It has a mass m attached to it It moves back and forth under the influence of gravity Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis19 L M Lets try to find an equation that describes the motion of the mass m makes. This will result in a Differential Equation

20 Basics of Accelerator Science & Technology at CERN Differential Equation Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis20 Restoring force due to gravity is -M g sinθ (force opposes motion) M L Mg  θ is small L is constant The distance from the centre = L θ (since θ is small) The velocity of mass M is: The acceleration of mass M is: Newton: Force = mass x acceleration

21 Basics of Accelerator Science & Technology at CERN Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis21 and Differential equation describing the motion of a pendulum at small amplitudes. Find a solution……Try a good “guess”…… Differentiate our guess (twice) Put this and our “guess” back in the original Differential equation. Solving a Differential Equation

22 Basics of Accelerator Science & Technology at CERN Solving a Differential Equation Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis22 Oscillation amplitude Oscillation frequency Now we have to find the solution for the following equation: Solving this equation gives: The final solution of our differential equation, describing the motion of a pendulum is as we expected :

23 Basics of Accelerator Science & Technology at CERN Position & Velocity Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis23 The differential equation that describes the transverse motion of the particles as they move around our accelerator. The solution of this second order describes oscillatory motion For any system, where the restoring force is proportional to the displacement, the solution for the displacement will be of the form:

24 Basics of Accelerator Science & Technology at CERN Phase Space Plot Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis24 Plot the velocity as a function of displacement: x x0x0 x0x0 It is an ellipse. As ωt advances by 2 π it repeats itself. This continues for (ω t + k 2π), with k=0,±1, ±2,..,..etc

25 Basics of Accelerator Science & Technology at CERN Oscillations in Accelerators Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis25 x = displacement x’ = angle = dx/ds ds x’x’ x dx x s Under the influence of the magnetic fields the particle oscillate

26 Basics of Accelerator Science & Technology at CERN Transverse Phase Space Plot Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis26 x φ φ = ωt is called the phase angle X-axis is the horizontal or vertical position (or time). Y-axis is the horizontal or vertical phase angle (or energy). This changes slightly the Phase Space plot X’ Position Angle

27 Basics of Accelerator Science & Technology at CERN Contents Vectors & Matrices Differential Equations Some Units we use CAS - 3 February 2014 - Chavannes de Bogis27Rende Steerenberg (BE/OP)

28 Basics of Accelerator Science & Technology at CERN Relativity CAS - 3 February 2014 - Chavannes de Bogis28 CPS velocity energy c SPS / LHC Einstein: energy increases not velocity } PSB Newton: Rende Steerenberg (BE/OP) More about “Relativity” by Werner Herr This afternoon

29 Basics of Accelerator Science & Technology at CERN Units: Joules versus eV Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis29 The unit most commonly used for Energy is Joules [J] In accelerator and particle physics we talk about eV…!? The energy acquired by an electron in a potential of 1 Volt is defined as being 1 eV 1 eV is 1 elementary charge ‘pushed’ by 1 Volt. 1 eV = 1.6 x 10 -19 Joules The unit eV is too small to be used currently, we use: 1 keV = 10 3 eV; 1 MeV = 10 6 eV; 1 GeV=10 9 eV; 1 TeV=10 12 eV,………

30 Basics of Accelerator Science & Technology at CERN Energy versus Momentum Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis30 Einstein’s formula:, which for a mass at rest is: The ratio between the total energy and the rest energy is Then the mass of a moving particle is: We can write: Momentum is: The ratio between the real velocity and the velocity of light is

31 Basics of Accelerator Science & Technology at CERN Energy versus Momentum Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis31 Therefore the units for – momentum are: MeV/c, GeV/c, …etc. – Energy are: MeV, GeV, …etc. Attention: when β=1 energy and momentum are equal when β<1 the energy and momentum are not equal Energy Momentum

32 Basics of Accelerator Science & Technology at CERN A Practical Example at PS Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis32 Kinetic energy at injection E kinetic = 1.4 GeV Proton rest energy E 0 =938.27 MeV The total energy is then: E = E kinetic + E 0 = 2.34 GeV We know that, which gives γ = 2.4921 We can derive, which gives β = 0.91597 Using we get p = 2.14 GeV/c In this case: Energy ≠ Momentum

33 Basics of Accelerator Science & Technology at CERN Rende Steerenberg (BE/OP)CAS - 3 February 2014 - Chavannes de Bogis33 Pure mathematics is, in its way, the poetry of logical ideas. Albert Einstein

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