Simple and convenient analytical formulas for studying the projectile motion in midair

Chudinov, Peter; Eltyshev, Vladimir; Barykin, Yuri

doi:10.1590/1806-9126-rbef-2017-0145

Cited by 5 publications

(6 citation statements)

References 7 publications

(15 reference statements)

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“…Based on this idea, in [7,8] their high-precision analytical solutions for the variables x, y, and t were obtained over a sufficiently large interval of variation of the variable θ. In the present work, these solutions are continued up to the limit value θ = −π/2.…”

Section: Obtaining Analytical Solutions To the Problemmentioning

confidence: 99%

“…Under the condition, θ < 0, nother approximation is required because the function f (θ) is odd. In [7,8] two approximations of the function f (θ) on the whole interval −π/2 < θ < π/2 were proposed. The first approximation uses a second-order polynomial, the second approximation uses a third-order polynomial.…”

Section: Obtaining Analytical Solutions To the Problemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Analytical construction of the projectile motion trajectory in midair

Chudinov¹,

Eltyshev²,

Barykin³

2021

Momento

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A classic problem of the motion of a projectile thrown at an angle to the horizon is studied. Air resistance force is taken into account with the use of the quadratic resistance law. An analytic approach is mainly applied for the investigation. Equations of the projectile motion are solved analytically for an arbitrarily large period of time. The constructed analytical solutions are universal, that is, they can be used for any initial conditions of throwing. As a limit case of motion, the vertical asymptote formula is obtained. The value of the vertical asymptote is calculated directly from the initial conditions of motion. There is no need to study the problem numerically. The found analytical solutions are highly accurate over a wide range of parameters. The motion of a baseball, a tennis ball, and a shuttlecock of badminton are presented as examples.

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Section: Obtaining Analytical Solutions To the Problemmentioning

confidence: 99%

Section: Obtaining Analytical Solutions To the Problemmentioning

confidence: 99%

See 1 more Smart Citation

Analytical construction of the projectile motion trajectory in midair

Chudinov¹,

Eltyshev²,

Barykin³

2021

Momento

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“…In [3], a very fruitful idea was proposed for calculating integrals (3). Based on this idea, in [4,5] there were obtained high-precision analytical solutions for the variables x, y and t over a sufficiently large interval of variation of the variable θ.…”

Section: The Obtaining An Analytical Solutions Of the Problemmentioning

confidence: 99%

“…Following other authors, we call this approach the analytic approach. From the point of view of the applied methods of solution, the present research is a development of the approaches used in [4,5]. The conditions of applicability of the quadratic resistance law are deemed to be fulfilled, i.e.…”

Section: Introductionmentioning

confidence: 99%

Analytical Investigation of Projectile Motion in Midair

Chudinov

Eltyshev

Barykin

2017

JAP

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I S S N 2347-3487 V o l u m e 1 3 N u m b e r 6 J o u r n a l o f A d v a n c e s i n P h y s i c s 4919 | P a g e J u n e 2 0 1 7 w w w . c i r w o r l d . c o m ABSTRACTHere is studied a classic problem of the motion of a projectile thrown at an angle to the horizon. The air drag force is taken into account as the quadratic resistance law. An analytic approach is used for the investigation. Equations of the projectile motion are solved analytically. All the basic functional dependencies of the problem are described by elementary functions. There is no need for to study the problem numerically. The found analytical solutions are highly accurate over a wide range of parameters. The motion of a baseball and a badminton shuttlecock are presented as examples.

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A simple determination of air drag using video tracker and modifiable projectile launcher

Wijaya¹,

Fauzi²,

Latief³

2019

Phys. Educ.

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The air drag constant for different nose shapes of projectiles is determined with the help of a simple method combining a projectile launcher, video tracking technique and spreadsheet computer code for simulating the motion. A projectile launcher with low-cost components is developed to study air drag in projectile motion. The launcher is based on air pressure and is easy to modify for different projectile types. The projectile motion is tracked using a video camera connected to a computer. The trajectory of the motion is then simulated with the help of the spreadsheet, and the air drag constant is adjusted to fit the observed data. The minimum error is used as the criteria for the best fitted air drag constant. Three types of projectiles, i.e.: conical, round, and cylindrical shape, are used in this experiment. The obtained air drag constants are in the range of 0.025-0.134. The conical shape has the lowest air drag constant as predicted.

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Simple and convenient analytical formulas for studying the projectile motion in midair

Cited by 5 publications

References 7 publications

Analytical construction of the projectile motion trajectory in midair

Analytical construction of the projectile motion trajectory in midair

Analytical Investigation of Projectile Motion in Midair

A simple determination of air drag using video tracker and modifiable projectile launcher

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