HW 03: Difference between revisions

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If <math> \left \langle \phi_n | \phi_m \right \rangle = \delta_{mn}</math> and <math> \phi_n \,\!</math> span the space of functions for which <math>x(t)\,\!</math> and <math>y(t)\,\!</math> are members and
If <math> \left \langle \phi_n | \phi_m \right \rangle = \delta_{mn}</math> and <math> \phi_n \,\!</math> span the space of functions for which <math>x(t)\,\!</math> and <math>y(t)\,\!</math> are members and
<math>x(t)= \sum _n a_n \phi_n (t)\,\!</math> and
<math>x(t)= \sum _n a_n \phi_n (t)\,\!</math> and
<math>y(t)= \sum _n b_n \phi_n (t)\,\!</math>, then show
<math>y(t)= \sum _m b_m \phi_m (t)\,\!</math>, then show


#<math> \left \langle x | y \right \rangle = \sum_n a_n b_n^*</math>
#<math> \left \langle x | y \right \rangle = \sum_n a_n b_n^*</math>
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{| border="0" cellpadding="0" cellspacing="0"
{| border="0" cellpadding="0" cellspacing="0"
|-
|-
|<math>\int_{-\infty}^{\infty} \sum _n a_n \phi_n (t) \sum _n b_n \phi_n (t)^* \,dt</math>
|<math>\int_{-\infty}^{\infty} \sum _n a_n \phi_n (t) \sum _m b_n \phi_n (t)^* \,dt</math>
|<math>=\sum_n a_n b_n \int_{-\infty}^{\infty} \phi_n (t) \phi_n (t)^* \,dt</math>
|<math>=\sum_n \sum _m a_n b_m^* \int_{-\infty}^{\infty} \phi_n (t) \phi_m (t)^* \,dt</math>
|-
|-
|
|
|<math>=\sum_n a_n b_n \left \langle \phi_n (t) | \phi_n (t)^* \right \rangle</math>
|<math>=\sum_n \sum _m a_n b_m^* \left \langle \phi_n (t) | \phi_m (t)^* \right \rangle</math>
|-
|-
|
|
|<math>=\sum_n a_n b_n \delta_{nn^*}</math>
|<math>=\sum_n \sum _m a_n b_m^* \delta_{nm^*}</math>
|-
|
|<math>=\sum_n a_n b_n^*</math>
|}
|}




#<math>\int_{-\infty}^{\infty} \sum _n a_n \phi_n (t) \sum _n a_n \phi_n (t)^* \,dt</math>
<math>\int_{-\infty}^{\infty} \sum _n a_n \phi_n (t) \sum _n a_n \phi_n (t)^* \,dt</math>

Revision as of 15:26, 12 November 2008

Problem

If and span the space of functions for which and are members and and , then show

Notes

  • This notation is called the Bra Ket , or Dirac notation. It denotes the inner product.

Solution