Latest revision as of 15:55, 15 January 2023

The set $\mathbb{R}$ of real numbers is a time scale. In this time scale, all derivatives reduce to the classical derivative and the integrals reduce to the classical integral.

$\mathbb{T}=\mathbb{R}$
Forward jump:	$\sigma(t)=t$	derivation
Forward graininess:	$\mu(t)=0$	derivation
Backward jump:	$\rho(t)=t$	derivation
Backward graininess:	$\nu(t)=0$	derivation
$\Delta$-derivative	$f^{\Delta}(t)=\displaystyle\lim_{h\rightarrow 0} \dfrac{f(t+h)-f(t)}{h}=f'(t)$	derivation
$\nabla$-derivative	$f^{\nabla}(t) =\displaystyle\lim_{h \rightarrow 0} \dfrac{f(t)-f(t-h)}{h}= f'(t)$	derivation
$\Delta$-integral	$\displaystyle\int_s^t f(\tau) \Delta \tau = \int_s^t f(\tau) d\tau$	derivation
$\nabla$-derivative	$\displaystyle\int_s^t f(\tau) \nabla \tau = \int_s^t f(\tau) d\tau$	derivation
$h_k(t,s)$	$h_k(t,s)=\dfrac{(t-s)^k}{k!}$	derivation
$\hat{h}_k(t,s)$	$\hat{h}_k(t,s)=\dfrac{(t-s)^k}{k!}$	derivation
$g_k(t,s)$	$g_k(t,s)=\dfrac{(t-s)^k}{k!}$	derivation
$\hat{g}_k(t,s)$	$\hat{g}_k(t,s)=\dfrac{(t-s)^k}{k!}$	derivation
$e_p(t,s)$	$e_p(t,s)=\exp \left( \displaystyle\int_s^t p(\tau) d\tau \right)$	derivation
$\hat{e}_p(t,s)$	$\hat{e}_p(t,s)=\exp \left( \displaystyle\int_s^t p(\tau) d\tau \right)$	derivation
Gaussian bell	$\mathbf{E}(t)=e^{-\frac{t^2}{2}}$	derivation
$\mathrm{sin}_p(t,s)=$	$\sin_p(t,s)=\sin\left( \displaystyle\int_s^t p(\tau) d\tau \right)$	derivation
$\mathrm{\sin}_1(t,s)$	$\sin_1(t,s)=\sin(t-s)$	derivation
$\widehat{\sin}_p(t,s)$	$\widehat{\sin}_p(t,s)=\sin\left( \displaystyle\int_s^t p(\tau) d\tau \right)$	derivation
$\mathrm{\cos}_p(t,s)$	$\cos_p(t,s)=\cos \left( \displaystyle\int_s^t p(\tau) d\tau \right)$	derivation
$\mathrm{\cos}_1(t,s)$	$\cos_1(t,s)=\cos(t-s)$	derivation
$\widehat{\cos}_p(t,s)$	$\widehat{\cos}_p(t,s)=\cos \left( \displaystyle\int_s^t p(\tau) d\tau \right)$	derivation
$\sinh_p(t,s)$	$\sinh_p(t,s)=$	derivation
$\widehat{\sinh}_p(t,s)$	$\widehat{\sinh}_p(t,s)=$	derivation
$\cosh_p(t,s)$	$\cosh_p(t,s)=$	derivation
$\widehat{\cosh}_p(t,s)$	$\widehat{\cos}_p(t,s)=$	derivation
Gamma function	$\Gamma_{\mathbb{R}}(x,s)=\displaystyle\int_0^{\infty} \left( \dfrac{\tau}{s} \right)^{x-1}e^{-\tau} d\tau$	derivation
Euler-Cauchy logarithm	$L(t,s)=$	derivation
Bohner logarithm	$L_p(t,s)=\log\left(\dfrac{p(t)}{p(s)}\right)$	derivation
Jackson logarithm	$\log_{\mathbb{T}} g(t)=$	derivation
Mozyrska-Torres logarithm	$L_{\mathbb{T}}(t)=$	derivation
Laplace transform	$\mathscr{L}_{\mathbb{R}}\{f\}(z;s)=\displaystyle\int_0^{\infty} f(\tau) e^{-z\tau} d\tau$	derivation
Hilger circle		derivation

References

Robert J. Marks II, Ian A. Gravagne and John M. Davis: A generalized Fourier transform and convolution on time scales (2008)... (next): Section 2.1(a)
Billy Jackson: Partial dynamic equations on time scales (2006)... (previous)... (next): Appendix

Examples of time scales
$\Huge\mathbb{R}$ Real numbers	$\Huge\mathbb{Z}$ Integers	$\Huge{h\mathbb{Z}}$ Multiples of integers	$\Huge\mathbb{Z}^2$ Square integers	$\Huge\mathbb{H}$ Harmonic numbers	$\Huge\mathbb{T}_{\mathrm{iso}}$ Isolated points
$\Huge\sqrt[n]{\mathbb{N}_0}$ nth root numbers	$\Huge\mathbb{P}_{a,b}$ Evenly spaced intervals	$\huge\overline{q^{\mathbb{Z}}}$ Quantum, $q>1$	$\huge\overline{q^{\mathbb{Z}}}$ Quantum, $q<1$	$\overline{\left\{\dfrac{1}{n} \colon n \in \mathbb{Z}^+\right\}}$ Closure of unit fractions	$\Huge\mathcal{C}$ Cantor set

@@ Line 1: / Line 1: @@
-The set $\mathbb{R}$ of real numbers is a [[time scale]]. In this time scale, all derivatives reduce to the clasical derivative and the integrals reduce to the [http://en.wikipedia.org/wiki/Riemann_integral Riemann integral].
+The set $\mathbb{R}$ of real numbers is a [[time scale]]. In this time scale, all derivatives reduce to the classical [https://en.wikipedia.org/wiki/Derivative derivative] and the integrals reduce to the classical [https://en.wikipedia.org/wiki/Integral integral].
 {| class="wikitable"
@@ Line 37: / Line 37: @@
 |-
 |[[Delta hk|$h_k(t,s)$]]
-|$h_k(t,s)=$
+|$h_k(t,s)=\dfrac{(t-s)^k}{k!}$
 |[[Derivation of delta hk for T=R|derivation]]
 |-
 |[[Nabla hk|$\hat{h}_k(t,s)$]]
-|$\hat{h}_k(t,s)=$
+|$\hat{h}_k(t,s)=\dfrac{(t-s)^k}{k!}$
 |[[Derivation of nabla hk for T=R|derivation]]
 |-
 |[[Delta gk|$g_k(t,s)$]]
-|$g_k(t,s)=$
+|$g_k(t,s)=\dfrac{(t-s)^k}{k!}$
 |[[Derivation of delta gk for T=R|derivation]]
 |-
 |[[Nabla gk|$\hat{g}_k(t,s)$]]
-|$\hat{g}_k(t,s)=$
+|$\hat{g}_k(t,s)=\dfrac{(t-s)^k}{k!}$
 |[[Derivation of nabla gk for T=R|derivation]]
 |-
@@ Line 61: / Line 61: @@
 |-
 |[[Gaussian bell]]
-|$\mathbf{E}(t)=$
+|$\mathbf{E}(t)=e^{-\frac{t^2}{2}}$
 |[[Derivation of Gaussian bell for T=R|derivation]]
 |-
@@ Line 73: / Line 73: @@
 |-
 |[[Nabla sine|$\widehat{\sin}_p(t,s)$]]
-|$\widehat{\sin}_p(t,s)=$
+|$\widehat{\sin}_p(t,s)=\sin\left( \displaystyle\int_s^t p(\tau) d\tau \right)$
 |[[Derivation of nabla sine sub p for T=R|derivation]]
 |-
@@ Line 85: / Line 85: @@
 |-
 |[[Nabla cosine|$\widehat{\cos}_p(t,s)$]]
-|$\widehat{\cos}_p(t,s)=$
+|$\widehat{\cos}_p(t,s)=\cos \left( \displaystyle\int_s^t p(\tau) d\tau \right)$
 |[[Derivation of nabla cos sub 1 for T=R|derivation]]
 |-
@@ Line 113: / Line 113: @@
 |-
 |[[Bohner logarithm]]
-|$L_p(t,s)=$
+|$L_p(t,s)=\log\left(\dfrac{p(t)}{p(s)}\right)$
 |[[Derivation of the Bohner logarithm for T=R|derivation]]
 |-
@@ Line 133: / Line 133: @@
 |-
 |}
+=References=
+*{{PaperReference|A generalized Fourier transform and convolution on time scales|2008|Robert J. Marks II|author2=Ian A. Gravagne|author3=John M. Davis|prev=|next=Multiples of integers}}: Section 2.1(a)
+* {{PaperReference|Partial dynamic equations on time scales|2006|Billy Jackson||prev=Time scale|next=Quantum q greater than 1}}: Appendix
+<center>{{:Time scales footer}}</center>

Difference between revisions of "Real numbers"

Latest revision as of 15:55, 15 January 2023

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