Sage Journals: Discover world-class research

Abstract

The aim of the study was to investigate differences in angular momentum values in the global coordinate system and the trunk coordinate system—the latter rotated about the throwing direction by the trunk lateral tilt angle at release for each style—throughout the entire baseball pitching between overhand, three-quarter, sidearm, and underhand styles, using waveform analyses. A total of 91 male Japanese amateur pitchers for the four deliveries of the pitches were videotaped and analyzed. Ball velocity was faster in overhand and three-quarter throws than underhand, and trunk lateral tilt angle at release was greatest for overhand, followed by three-quarter, sidearm, and underhand. System and trunk-and-head angular momentum values around the axis along the throwing direction in the global coordinate system were largely different among the four styles, distinguishing the styles from each other. Although the upper body angular momentum values around the axis perpendicular to the throwing direction in the global coordinate system substantially differ among delivery styles, differences in the area around the corresponding axis in the trunk coordinate system were minimal, and the differences in angular momentum values (overhand, three-quarter > three-quarter > underhand) mainly found around the trunk longitudinal axis, suggesting that the angular momentum around the trunk longitudinal axis is essential for achieving a fast ball.

Keywords

Body segments trunk lateral tilt angle coordinate transformation waveform analysis 3D video motion analysis

Get full access to this article

View all access options for this article.

References

Miyanishi

Shimada

Kawamura

, et al. Classification of four pitching styles in Japanese baseball players. Int J Sports Sci Coach 2023; 18: 2198–2204.

Escamilla

Slowik

Diffendaffer

, et al. Differences among overhand, 3-Quarter, and sidearm pitching biomechanics in professional baseball players. J Appl Biomech 2018; 34: 377–385.

Escamilla

Slowik

Fleisig

GS.

Effects of contralateral trunk tilt on shoulder and elbow injury risk and pitching biomechanics in professional baseball pitchers. Am J Sports Med 2023; 51: 935–941.

Atwater

AE.

Biomechanics of overarm throwing movements and of throwing injuries. In: Hutton

Miller

(eds) Exercise and Sport Sciences Reviews 7. Philadelphia: Franklin Institute Press, 1979, pp.43–85.

Bun

JW.

Scientific principles of coaching. New Jersey: Prentice-Hall Inc, 1972, pp.8–11, pp.164–171.

Kreighbaum

Barthels

KM.

Biomechanics-A qualitative approach for studying human movement. 4th ed. Massachusetts: Allyn & Bacon, 1996, pp.335–354.

Morehouse

Cooper

JM.

Kinesiology. London: Henry Kimpton, 1950, pp.117–129.

Toyoshima

Hoshikawa

Miyashita

, et al. Contribution of the body parts to throwing performance. In: Nelson

Morehouse

(eds) Biomechanics IV. Maryland: University Park Press, 1974, pp.169–174.

Alizadeh

Matts

How anterior pelvic tilt affects the lower extremity kinematics during the late swing phase in soccer players while running: a time series analysis. Hum Mov Sci 2019; 66: 459–466.

10.

Eerdekens

Deschamps

Staes

The impact of walking speed on the kinetic behaviour of different foot joints. Gait Posture 2018; 68: 375–381.

11.

Abdel-Aziz

Karara

HM.

Direct linear transformation from comparator coordinates into object space coordinates in close-range photogrammetry. In: Symposium on CloseRange photogrammetry, Illinois, USA, 26–29 January 1971, pp.1–18, Virginia: ASP.

12.

Woltring

HJ.

A Fortran package for generalized, cross-validatory spline smoothing and differentiation. Advan Eng Soft 1986; 8: 104–113.

13.

Well

Winter

. Assessment of signal and noise in the kinematics of normal, pathological and sporting gait. In: Proceedings of the special conference of the Canadian society for biomechanics-Human Locomotion I, 27–29 October 1980, pp.92–93. London: Ontario.

14.

Winter

DA.

Biomechanics and Motor Control of Human Movement. 4th ed. New York: John Wiley & Sons, 2009, pp.26–44.

15.

De Leva

. Adjustments to Zatsiorsky−Seluyanov’s segment inertia parameters. J Biomech 1996; 29: 1223–1230.

16.

Zatsiorsky

Seluyanov

Chugunova

LG.

Methods of determining mass-inertial characteristics of human body segments. In: Chernyi

Regirer

(eds) Contemporary Problems of Biomechanics. Massachusetts: CRC, 1990, pp.272–291.

17.

Dapena

A method to determine the angular momentum of a human body about three orthogonal axes passing through its center of gravity. J Biomech 1978; 11: 251–256.

18.

Dapena

Contributions of angular momentum and catting to the twist rotation in high jumping. J Appl Biomech 1997; 13: 239–253.

19.

Fleisig

Barrentine

Zheng

, et al. Kinematic and kinetic comparison of baseball pitching among various levels of development. J Biomech 1999; 32: 1371–1375.

20.

Werner

Flesig

Dillman

, et al. Biomechanics of the elbow during baseball pitching. J Orthop Sports Phys Ther 1993; 17: 274–278.

21.

Muraki

Koyama

, et al. A biomechanical method to establish a standard motion and identify critical motion by motion variability: with examples of high jump and sprint running. Bullet Inst Health Sport Sci 2007; 30: 5–12.

22.

Pataky

TC.

One-dimensional statistical parametric mapping in Python. Comp Meth Biomech Biomed Eng 2012; 15: 295–301.

23.

Kageyama

Sugiyama

Takai

, et al. Kinematic and kinetic profiles of trunk and lower limbs during baseball pitching in collegiate pitchers. J Sports Sci Med 2014; 13: 742–750.

24.

Stodden

Fleisig

McLean

, et al. Relationship of biomechanical factors to baseball pitching velocity: within pitcher variation. J Appl Biomech 2005; 21: 44–56.

25.

Stodden

Fleisig

McLean

, et al. Relationship of pelvis and upper torso kinematics to pitched baseball velocity. J Appl Biomech 2001; 17: 164–172.

Angular momentum of the overhand,three-quarter,sidearm,and underhand delivery styles in the fastball baseball pitch

Abstract

Keywords

Get full access to this article

References