Draft:Coimbra derivative

Submission declined on 12 December 2023 by Newystats (talk). This draft's references do not show that the subject qualifies for a Wikipedia article. In summary, the draft needs multiple published sources that are: in-depth (not just passing mentions about the subject) reliable secondary independent of the subject Make sure you add references that meet these criteria before resubmitting. Learn about mistakes to avoid when addressing this issue. If no additional references exist, the subject is not suitable for Wikipedia. If you would like to continue working on the submission, click on the "Edit" tab at the top of the window. If you have not resolved the issues listed above, your draft will be declined again and potentially deleted. If you need extra help, please ask us a question at the AfC Help Desk or get live help from experienced editors. Please do not remove reviewer comments or this notice until the submission is accepted. Where to get help If you need help editing or submitting your draft, please ask us a question at the AfC Help Desk or get live help from experienced editors. These venues are only for help with editing and the submission process, not to get reviews. If you need feedback on your draft, or if the review is taking a lot of time, you can try asking for help on the talk page of a relevant WikiProject. Some WikiProjects are more active than others so a speedy reply is not guaranteed. How to improve a draft Wikipedia:Contributing to Wikipedia – a basic overview on how to edit Wikipedia. Help:Wikitext – how to use the markup Help:Referencing for beginners – how to include references Wikipedia:Article development – how to develop your article Wikipedia:Writing better articles – how to improve your article Wikipedia:Verifiability – make sure your article includes reliable third-party sources You can also browse Wikipedia:Featured articles and Wikipedia:Good articles to find examples of Wikipedia's best writing on topics similar to your proposed article. Improving your odds of a speedy review To improve your odds of a faster review, tag your draft with relevant WikiProject tags using the button below. This will let reviewers know a new draft has been submitted in their area of interest. For instance, if you wrote about a female astronomer, you would want to add the Biography, Astronomy, and Women scientists tags. Add tags to your draft Editor resources Find sources: Google (books · news · scholar · free images · WP refs) · FENS · JSTOR · TWL Easy tools: Citation bot (help) | Advanced: Fix bare URLs Declined by Newystats 4 months ago. Last edited by Newystats 13 days ago. Reviewer: Inform author. Resubmit Please note that if the issues are not fixed, the draft will be declined again.

Submission declined on 7 December 2023 by Stuartyeates (talk). This submission provides insufficient context for those unfamiliar with the subject matter. Please see the guide to writing better articles for information on how to better format your submission. Declined by Stuartyeates 5 months ago.

• Comment: Some or all of this content might be usefully added to Fractional calculus Newystats (talk) 06:11, 24 April 2024 (UTC)

• Comment: Declined, then re-submitted with no edits. Please address the notability concerns. Particularly, show that there are secondary, not just primary references to this topic. Also, only 4 of the 15 references here are not by Coimbra, not a good indication of widespread coverage of the topic. Newystats (talk) 11:12, 12 December 2023 (UTC)

• Comment: It would be best to start with an article on order derivatives in general. Newystats (talk) 06:01, 12 December 2023 (UTC)

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The Coimbra derivative is the most versatile variable order derivative, and consequently it is the most often used for physical modeling:^[1]

For ${\displaystyle q(t)<1}$
$${\displaystyle {\begin{aligned}^{\mathbb {C} }_{a}\mathbb {D} ^{q(t)}f(t)={\frac {1}{\Gamma [1-q(t)]}}\int _{0^{+}}^{t}(t-\tau )^{-q(t)}{\frac {d\,f(\tau )}{d\tau }}d\tau \,+\,{\frac {(f(0^{+})-f(0^{-}))\,t^{-q(t)}}{\Gamma (1-q(t))}},\end{aligned}}}$$

where the lower limit ${\displaystyle a}$ can be taken as either ${\displaystyle 0^{-}}$ or ${\displaystyle -\infty }$ as long as ${\displaystyle f(t)}$ is identically zero from or ${\displaystyle -\infty }$ to ${\displaystyle 0^{-}}$. Note that this operator returns the correct fractional derivatives for all values of ${\displaystyle t}$ and can be applied to either the dependent function itself ${\displaystyle f(t)}$ with a variable order of the form ${\displaystyle q(f(t))}$ or to the independent variable with a variable order of the form ${\displaystyle q(t)}$.${\displaystyle ^{[1]}}$

The Coimbra derivative defined above returns the correct value of the zero-th order derivative ${\displaystyle (^{\mathbb {C} }\mathbb {D} ^{0}f(t)=f(t))}$ when ${\displaystyle q(t)=0}$ and returns the first derivative ${\displaystyle (^{\mathbb {C} }\mathbb {D} ^{1}f(t)=f'(t))}$ when ${\displaystyle q(t)\rightarrow 1}$. Also, the operator returns the ${\displaystyle p}$-th derivative of ${\displaystyle f(t)}$ when ${\displaystyle q(t)=p}$, a necessary property for dynamical modeling that is often overlooked when the focus is placed on mathematical properties that resemble fixed order differential operators (for example, whether the operators abide by the exponent rule, etc.). Also of great importance to dynamic modeling is the fact that this operator is dynamically consistent with causal behavior in the initial conditions. In other words, when ${\displaystyle f(t)}$ is a true constant from ${\displaystyle -\infty }$ to the initial time ${\displaystyle (t=0+)}$, the Coimbra operator returns zero for all values of ${\displaystyle q(f(t))}$. However, if ${\displaystyle f(t)}$ is discontinuous between ${\displaystyle t=0^{-}}$ and ${\displaystyle t=0^{+}}$, the operator returns the appropriate Heaviside contribution to the integral value of ${\displaystyle ^{\mathbb {C} }\mathbb {D} ^{q(t)}(t)}$. In accordance with this causal definition, we take the value of the physical variable ${\displaystyle f(t)}$ to be identically null from ${\displaystyle -\infty }$ to ${\displaystyle 0^{-}}$ as a representation of dynamic equilibrium. A nonzero initial condition is treated as a Heaviside function at ${\displaystyle t=0}$, and, therefore, it is included in the second term of the definition of the operator above. This way, the Coimbra operator allows for discontinuities at the initial condition, as long as there is dynamic equilibrium for ${\displaystyle -\infty <t\leq 0^{-}}$, i.e., when ${\displaystyle f(t\leq 0^{-})=0}$. Since one is free to place the initial counter of time at any given instant, this operator is both causal and allows for discontinuous initial conditions.:^[2]

The Coimbra derivative can be generalized to any order^[3], leading to the Coimbra Generalized Order Differintegration Operator (GODO)^[4]

For ${\displaystyle q(t)<m}$
$${\displaystyle {\begin{aligned}^{\mathbb {\quad C} }_{\,\,-\infty }\mathbb {D} ^{q(t)}f(t)={\frac {1}{\Gamma [m-q(t)]}}\int _{0^{+}}^{t}(t-\tau )^{m-1-q(t)}{\frac {d^{m}f(\tau )}{d\tau ^{m}}}d\tau \,+\,\sum _{n=0}^{m-1}{\frac {({\frac {d^{n}f(t)}{dt^{n}}}|_{0^{+}}-{\frac {d^{n}f(t)}{dt^{n}}}|_{0^{-}})\,t^{n-q(t)}}{\Gamma [n+1-q(t)]}},\end{aligned}}}$$

where ${\displaystyle m}$ is an integer larger than the larger value of ${\displaystyle q(t)}$ for all values of ${\displaystyle t}$. Note that the second (summation) term on the right side of the definition above can be expressed as

$${\displaystyle {\begin{aligned}{\frac {1}{\Gamma [m-q(t)]}}\sum _{n=0}^{m-1}\{[{\frac {d^{n}\!f(t)}{dt^{n}}}|_{0^{+}}-{\frac {d^{n}\!f(t)}{dt^{n}}}|_{0^{-}}]\,t^{n-q(t)}\prod _{j=n+1}^{m-1}[j-q(t)]\}\end{aligned}}}$$

so to keep the denominator on the positive branch of the Gamma (${\displaystyle \Gamma }$) function and for ease of numerical calculation.

Applications and Numerical Implementation

A number of applications in both mechanics and optics can be found in the works by Coimbra and collaborators,^{[5][6][7][8][9][10][11]} as well as additional applications to physical problems and numerical implementations studied in a number of works by other authors^{[12][13][14][15]}

References

1. C. F. M. Coimbra (2003) “Mechanics with Variable Order Differential Equations,” Annalen der Physik (12), No. 11-12, pp. 692-703.
2. C. M. Soon, C. F. M. Coimbra, and M. H. Kobayashi (2005). “The Variable Viscoelasticity Oscillator,” Annalen der Physik (14), N.6, pp. 378-389.
3. C. F. M. Coimbra “Methods of using generalized order differentiation and integration of input variables to forecast trends," U.S. Patent Application 13,641,083 (2013).
4. J. Orosco and C. F. M. Coimbra (2018) “Variable-order Modeling of Nonlocal Emergence in Many-body Systems: Application to Radiative Dispersion,” Physical Review E (98), 032208.
5. L. E. S. Ramirez, and C. F. M. Coimbra (2007) “A Variable Order Constitutive Relation for Viscoelasticity”– Annalen der Physik (16) 7-8, pp. 543-552.
6. H. T. C. Pedro, M. H. Kobayashi, J. M. C. Pereira, and C. F. M. Coimbra (2008) “Variable Order Modeling of Diffusive-Convective Effects on the Oscillatory Flow Past a Sphere” – Journal of Vibration and Control, (14) 9-10, pp. 1569-1672.
7. G. Diaz, and C. F. M. Coimbra (2009) “Nonlinear Dynamics and Control of a Variable Order Oscillator with Application to the van der Pol Equation” – Nonlinear Dynamics, 56, pp. 145—157.
8. L. E. S. Ramirez, and C. F. M. Coimbra (2010) “On the Selection and Meaning of Variable Order Operators for Dynamic Modeling”– International Journal of Differential Equations Vol. 2010, Article ID 846107.
9. L. E. S. Ramirez and C. F. M. Coimbra (2011) “On the Variable Order Dynamics of the Nonlinear Wake Caused by a Sedimenting Particle,” Physica D (240) 13, pp. 1111-1118.
10. E. A. Lim, M. H. Kobayashi and C. F. M. Coimbra (2014) “Fractional Dynamics of Tethered Particles in Oscillatory Stokes Flows,” Journal of Fluid Mechanics (746) pp. 606-625.
11. J. Orosco and C. F. M. Coimbra (2016) “On the Control and Stability of Variable Order Mechanical Systems” Nonlinear Dynamics, (86:1), pp. 695–710.
12. E. C. de Oliveira, J. A. Tenreiro Machado (2014), "A Review of Definitions for Fractional Derivatives and Integral", Mathematical Problems in Engineering, vol. 2014, Article ID 238459.
13. S. Shen, F. Liu, J. Chen, I. Turner, and V. Anh (2012) "Numerical techniques for the variable order time fractional diffusion equation" Applied Mathematics and Computation Volume 218, Issue 22, pp. 10861-10870.
14. H. Zhang and S. Shen, "The Numerical Simulation of Space-Time Variable Fractional Order Diffusion Equation," Numer. Math. Theor. Meth. Appl. Vol. 6, No. 4, pp. 571-585.
15. H. Zhang, F. Liu, M. S. Phanikumar, and M. M. Meerschaert (2013) "A novel numerical method for the time variable fractional order mobile-immobile advection-dispersion model," Computers & Mathematics with Applications, 66, issue 5, pp. 693–701.