Understanding Sprinting Biomechanics Techniques

Hi it's Wasim from Curious Doc. We're going to continue with this theme of analysing the biomechanics in sports except today we're going to talk about sprinting. I also wanted to make this because it seems like there's so much misinformation out there. Almost everyone has a different opinion about leg movement, arm swing and foot positioning etc. And almost no one backs this up with scientific reasoning. Let's first look at the acceleration phase, the first 10 or so meters of the race where the sprinter is gaining speed. Here the goal is to lean the entire body forward and maximise length of time the foot is planted into the ground. If you look at the foot pushing off the ground, you can see the force vector is being applied in this direction. When we break down the force vector into horizontal and vertical components, you can see that some of the force is being used to propel you forwards and some of the force is vertical, keeping your body off the ground. Obviously, sprinting is all about moving horizontally as quickly as possible, so the aim is to maximise this horizontal component which is done by leaning the body forwards. As you can see, the torso and shin should be parallel to each other, forming an acute angle with the ground. In this case it's about 45 degrees with the ground but the more acute the angle, the more horizontal force you produce and the faster you'll accelerate. However, you have to be careful because if you lean too much, there won't be enough vertical force keeping your body up which means that you'll start to stumble. Your legs also won't be able to move underneath your body fast enough to catch your falling body. One trick to counteract a stumble is to drag the trailing foot just above the ground instead of bringing it up high like you're used to. This way the foot has to travel a lot less distance and can reposition underneath your center of mass before you stumble. So in summary, the aim of the acceleration phase to create an aggressive forward lean to maximise horizontal force production whilst ensuring there's just enough vertical force to keep your body from stumbling. Once you've reaching maximum velocity, you transition into the maintenance phase, where the biomechanics of the body changes completely. The stride length increases and the contact time between the foot and ground decreases. The body also needs to straighten out and become more upright. A lot of new runners will assume that the body lean will help in the maintenance phase like it does in the acceleration phase but unfortunately, since you're no longer accelerating, it only works against you and slows you down. A 5-10 degree lean is okay but any more and the range of motion of the legs will be severely compromised and as we'll see soon, the center of mass moves to a suboptimal position over the legs. Let's talk about the phases of running and the goals of each phase by concentrating on one leg at a time. When the foot is on the ground, it's called the drive phase. At the beginning of the drive phase, when the foot hits the ground, the goal is to step directly underneath or just in front of your center of mass. If the foot steps too far in front of the center of mass, we can see a force is applied in this direction. And as we know, according to Newton's 3rd law, there's an equal and opposite force in this direction which is called the ground reaction force. When the foot is in front of the center of mass, this ground reaction force is in the opposite direction to the runner, acting like a braking force and causing the runner to slow down. It's a common problem for all new runners and is often compensating by activating the hamstring muscles to pull on ground with the foot. This is a really inefficient way of running and tires you out quickly. However, if you focus on landing the foot underneath your center of mass, a lot of the force is in the horizontal direction. If we look at a video of Usain Bolt, you can see that his leg starts to move backwards while it's still in the air. And the foot only hits the ground whilst it's underneath his hips. Also note how his knee is above his foot at the point of contact so he's pushing with his legs instead of pulling. This is another reason why we need to have an upright torso while in the maintenance phase of running. If you lean too far forward, your foot will tend to land behind the center of mass. As a result, you're missing out on a big part of the drive phase and won't be able to transfer energy into the ground as efficiently. After initial contact with the ground, we enter the middle part of the drive phase. The aim here is to plantarflex the ankle with the calf muscles, extend at the hip with the glute and hamstring muscles and keep the torso upright using the core. This is often referred to as triple extension and the whole point of it is to use the entire range of motion of the legs whilst keeping the body upright. However, the term triple extension is controversial because people often refer to the knees being fully extended. If you watch any elite runner, you'll notice the knee is always in a tiny bit of flexion throughout the entire range of motion. At no point, do the knees fully lock out. And this is for good reason, because locking out the knees in full extension creates a biomechanical DISadvantage to your hamstring muscles. The hamstring originates at the pelvis and inserts on the tibia (and fibula) just below the knee. In engineering, this is called a class 3 lever, with a pivot at the knee joint, the effort at the insertion of the hamstring and the load being applied to the distal tibia where the foot is. Now if you imagine your knee is fully locked out, you can see that no matter how much you pull with the hamstring, the knee won't bend. This is why the knees are always slightly bent in running or rock climbers always have a slight bend in their arms when doing an isometric pullup. Next, we have the recovery phase where the leg is in the air. This is an often overlooked part of running but extremely important. The recovery of the leg determines the speed and momentum of the other leg's drive phase. So the aim is to recover the leg as quickly as possible so it's ready to hit the ground running for the drive phase, pun intended. To optimise the recovery phase the knee should be almost fully flexed and the ankle should be dorsiflexed. This decreases the moment of inertia produced by the leg so that less effort is required to swing the leg forwards. You can think of the moment of inertia as the torque required to rotate an object from a standstill, so if you imagine holding a hammer at arms length, it's much harder to rotate at the shoulder compared to when the hammer is closer to the body. It's also a similar concept when ice skaters spin really fast when they bring their arms and legs in. And the same thing happens in running, the knee and ankle is brought closer to the hips so that the moment of inertia is smaller and the leg can recover quicker. And the faster the recovery, the more faster and forceful the drive phase of the other leg will be. So in summary, for the maintenance phase of running, you want to land with your foot underneath your center of mass to minimise the braking force. Then you want to push off the ground using the calf muscles to plantarflex the ankle, the glutes and hamstrings to extend at the hip and the core to keep the torso upright. And finally when your foot leave the ground, you want to flex at the knee and dorsiflex at the ankle to minimise the moment of inertia of the leg and speed up the recovery phase. As you can see the whole motion is rhythmical and smooth. If you look at the position of the hip, it doesn't bounce up and down but instead seems to float above the ground. This shows that a lot of the energy is going into horizontal motion and isn't being wasted in doing mini-jumps with each stride. Sprinting biomechanics is one of the most complex things I've learnt and there's a lot of things that I didn't have time to cover in this video such as how to push off the blocks at the start or how to move the arms correctly. So if you enjoyed this video and would like to see part 2, consider subscribing with notifications on. Thank you.

Hi it's Wasim from Curious Doc. We're 
going to continue with this theme of   analysing the biomechanics in sports except 
today we're going to talk about sprinting.   I also wanted to make this because it seems 
like there's so much misinformation out there.   Almost everyone has a different 
opinion about leg movement,   arm swing and foot positioning etc. And almost 
no one backs this up with scientific reasoning. Let's first look at the acceleration phase, 
the first 10 or so meters of the race where   the sprinter is gaining speed. Here the goal is to 
lean the entire body forward and maximise length   of time the foot is planted into the ground. If 
you look at the foot pushing off the ground, you   can see the force vector is being applied in this 
direction. When we break down the force vector   into horizontal and vertical components, you can 
see that some of the force is being used to propel   you forwards and some of the force is vertical, 
keeping your body off the ground. Obviously,   sprinting is all about moving horizontally as 
quickly as possible, so the aim is to maximise   this horizontal component which is done by leaning 
the body forwards. As you can see, the torso and   shin should be parallel to each other, forming 
an acute angle with the ground. In this case it's   about 45 degrees with the ground but the more 
acute the angle, the more horizontal force you   produce and the faster you'll accelerate. However, 
you have to be careful because if you lean too   much, there won't be enough vertical force keeping 
your body up which means that you'll start to   stumble. Your legs also won't be able to move 
underneath your body fast enough to catch your   falling body. One trick to counteract a stumble 
is to drag the trailing foot just above the ground   instead of bringing it up high like you're used 
to. This way the foot has to travel a lot less   distance and can reposition underneath your center 
of mass before you stumble. So in summary, the aim   of the acceleration phase to create an aggressive 
forward lean to maximise horizontal force   production whilst ensuring there's just enough 
vertical force to keep your body from stumbling. Once you've reaching maximum velocity, 
you transition into the maintenance phase,   where the biomechanics of the body 
changes completely. The stride length   increases and the contact time between the foot 
and ground decreases. The body also needs to   straighten out and become more upright. A lot 
of new runners will assume that the body lean   will help in the maintenance phase like it does 
in the acceleration phase but unfortunately,   since you're no longer accelerating, it only 
works against you and slows you down. A 5-10   degree lean is okay but any more and the range of 
motion of the legs will be severely compromised   and as we'll see soon, the center of mass 
moves to a suboptimal position over the legs. Let's talk about the phases of running and 
the goals of each phase by concentrating on   one leg at a time. When the foot is on the ground, 
it's called the drive phase. At the beginning of   the drive phase, when the foot hits the ground, 
the goal is to step directly underneath or just   in front of your center of mass. If the foot 
steps too far in front of the center of mass,   we can see a force is applied in this direction. 
And as we know, according to Newton's 3rd law,   there's an equal and opposite force in this 
direction which is called the ground reaction   force. When the foot is in front of the center 
of mass, this ground reaction force is in the   opposite direction to the runner, acting like a 
braking force and causing the runner to slow down.   It's a common problem for all new runners and is 
often compensating by activating the hamstring   muscles to pull on ground with the foot. This 
is a really inefficient way of running and   tires you out quickly. However, if you focus on 
landing the foot underneath your center of mass,   a lot of the force is in the horizontal direction. 
If we look at a video of Usain Bolt, you can see   that his leg starts to move backwards while 
it's still in the air. And the foot only hits   the ground whilst it's underneath his hips. Also 
note how his knee is above his foot at the point   of contact so he's pushing with his legs instead 
of pulling. This is another reason why we need to   have an upright torso while in the maintenance 
phase of running. If you lean too far forward,   your foot will tend to land behind the center 
of mass. As a result, you're missing out on a   big part of the drive phase and won't be able to 
transfer energy into the ground as efficiently. After initial contact with the ground, we enter 
the middle part of the drive phase. The aim here   is to plantarflex the ankle with the calf muscles, 
extend at the hip with the glute and hamstring   muscles and keep the torso upright using the core. 
This is often referred to as triple extension   and the whole point of it is to use the entire 
range of motion of the legs whilst keeping the   body upright. However, the term triple extension 
is controversial because people often refer to   the knees being fully extended. If you watch 
any elite runner, you'll notice the knee is   always in a tiny bit of flexion throughout 
the entire range of motion. At no point,   do the knees fully lock out. And this is for good 
reason, because locking out the knees in full   extension creates a biomechanical DISadvantage to 
your hamstring muscles. The hamstring originates   at the pelvis and inserts on the tibia (and 
fibula) just below the knee. In engineering,   this is called a class 3 lever, with a pivot 
at the knee joint, the effort at the insertion   of the hamstring and the load being applied to the 
distal tibia where the foot is. Now if you imagine   your knee is fully locked out, you can see that 
no matter how much you pull with the hamstring,   the knee won't bend. This is why the knees are 
always slightly bent in running or rock climbers   always have a slight bend in their arms when doing 
an isometric pullup. Next, we have the recovery   phase where the leg is in the air. This is an 
often overlooked part of running but extremely   important. The recovery of the leg determines the 
speed and momentum of the other leg's drive phase.   So the aim is to recover the leg as quickly as 
possible so it's ready to hit the ground running   for the drive phase, pun intended. To optimise 
the recovery phase the knee should be almost   fully flexed and the ankle should be dorsiflexed. 
This decreases the moment of inertia produced by   the leg so that less effort is required to swing 
the leg forwards. You can think of the moment of   inertia as the torque required to rotate an object 
from a standstill, so if you imagine holding a   hammer at arms length, it's much harder to rotate 
at the shoulder compared to when the hammer is   closer to the body. It's also a similar concept 
when ice skaters spin really fast when they bring   their arms and legs in. And the same thing happens 
in running, the knee and ankle is brought closer   to the hips so that the moment of inertia 
is smaller and the leg can recover quicker.   And the faster the recovery, the more faster and 
forceful the drive phase of the other leg will be. So in summary, for the maintenance 
phase of running, you want to land   with your foot underneath your center 
of mass to minimise the braking force.   Then you want to push off the ground using 
the calf muscles to plantarflex the ankle,   the glutes and hamstrings to extend at the 
hip and the core to keep the torso upright.   And finally when your foot leave the ground, 
you want to flex at the knee and dorsiflex at   the ankle to minimise the moment of inertia 
of the leg and speed up the recovery phase. As you can see the whole motion 
is rhythmical and smooth.   If you look at the position of the 
hip, it doesn't bounce up and down   but instead seems to float above the ground. 
This shows that a lot of the energy is   going into horizontal motion and isn't being 
wasted in doing mini-jumps with each stride. Sprinting biomechanics is one of 
the most complex things I've learnt   and there's a lot of things that I 
didn't have time to cover in this video   such as how to push off the blocks at the start or 
how to move the arms correctly. So if you enjoyed   this video and would like to see part 2, consider 
subscribing with notifications on. Thank you.

Transcript for:Understanding Sprinting Biomechanics Techniques

Transcript for:
Understanding Sprinting Biomechanics Techniques