文章探讨了滑板运动员在半管中持续运动的原理，即通过类似调节游乐场秋千的方式，改变自身重心来为系统注入动能。苏黎世联邦理工学院的研究人员对此建立了模型，并将其与经验丰富和缺乏经验的滑板运动员的视频数据进行比较，发现该模型适用于经验丰富的运动员。此研究发表在《物理评论研究》上，该模型还可能用于理解其他运动的物理原理。

🎈滑板运动员在半管中运动时，顶部的重力势能会因摩擦迅速损失，而持续运动的关键在于类似调节秋千的方式，通过改变重心来注入动能。在半管中，运动员在滑板经过平坦部分时蹲下，在斜坡弯曲上升时从板上推起，以减少系统的转动惯量，根据角动量守恒定律，运动员必须加速。

💡苏黎世联邦理工学院的Florian Kogelbauer及日本的同事们建立了一个模型，该模型考虑了熟练的滑板运动员如何相对于半管表面调节他们的质心。研究团队将模型与经验丰富和缺乏经验的滑板运动员在半管中运动的视频数据进行了比较。

🎉研究人员发现经验丰富的滑板运动员确实符合他们的泵送模型。他们计划扩展该模型，以包括滑板运动员在泵送过程中所做的其他动作。此外，该模型还可用于更好地理解如跳台滑雪等其他运动的物理学原理，此研究发表在《物理评论研究》上。

If you have been watching skateboarding at the Olympics, you may be wondering how the skaters manage to keep going up and down ramps long after friction should have consumed their initial gravitational potential energy.

That process is called pumping, and most skaters will learn how to do it by going back and forth on a half-pipe. If you are not familiar with the lingo, a half-pipe comprises two ramps that are connected by a lower (sometimes flat) middle section. A good skateboarder can skate up the side of a ramp, turn around and do the same on the other side – and continue to oscillate back and forth in the half-pipe.

What’s obvious about the physics of this scenario is that the gravitational potential energy of the skater while at the top of the half-pipe will be quickly lost to friction. So how does a skater keep going? How do they pump kinetic energy into the system?

Variable pendulum

It turns out that the process is similar to an obscure way that you can keep a playground swing going – by standing on the seat and shifting your centre of mass by squatting down in the centre of a swing and rising up at both ends of a swing (see video below). This can be understood in terms of a pendulum with a length that varies in a regular way – and that is how Florian Kogelbauer at ETH Zurich and colleagues in Japan have modelled pumping in a skateboard half-pipe.

Their model considers how a skilled skater modulates their centre of mass relative to the surface of the half-pipe. Essentially this involves crouching down as the skateboard travels across the flat bit of the halfpipe, then pushing up from the board during the curved ascent of the ramp. Pushing up reduces the moment of inertia of the system, and conservation of angular momentum dictates that the skater must speed up.

The team compared their model to video data of experienced and inexperienced skaters pumping a half-pipe. They found that experienced skaters did indeed adhere to their model of pumping. They now plan to extend their model to include other movements done by skaters during pumping. They also say that their model could be used to better understand the physics of other sports such as ski jumping.

The research is described in Physical Review Research.

And if you are interested in the physics of the playground swing, check out the video below.

 

The post Pumping on a half-pipe: physicists model a skateboarding skill appeared first on Physics World.