Side View Swing Arm Height given Percentage Anti Lift Solution

STEP 0: Pre-Calculation Summary
Formula Used
Side View Swing Arm Height = Percentage Anti Lift/((Percentage Rear Braking)*(1/Side View Swing Arm Length)/(Height of CG above Road/Independent Wheelbase of Vehicle))
SVSAh = %ALr/((%Br)*(1/SVSAl)/(h/bind))
This formula uses 6 Variables
Variables Used
Side View Swing Arm Height - (Measured in Meter) - Side View Swing Arm Height is the vertical distance from the wheel center to the upper pivot point of the swing arm in an independent suspension system.
Percentage Anti Lift - Percentage Anti Lift is the percentage of the weight transfer that is resisted by the suspension during acceleration or braking in an independent suspension system.
Percentage Rear Braking - Percentage Rear Braking is the proportion of braking force applied to the rear wheels in an independent suspension system to maintain vehicle stability and control.
Side View Swing Arm Length - (Measured in Meter) - Side View Swing Arm Length is the distance from the axis of the coil spring to the axis of the wheel in an independent suspension system.
Height of CG above Road - (Measured in Meter) - Height of CG above Road is the vertical distance from the road surface to the centre of gravity of a vehicle's sprung mass.
Independent Wheelbase of Vehicle - (Measured in Meter) - Independent Wheelbase of Vehicle is the distance between the center point of the front wheel and the center point of the rear wheel of a vehicle.
STEP 1: Convert Input(s) to Base Unit
Percentage Anti Lift: 2.74 --> No Conversion Required
Percentage Rear Braking: 60.88889 --> No Conversion Required
Side View Swing Arm Length: 600 Millimeter --> 0.6 Meter (Check conversion ​here)
Height of CG above Road: 10000 Millimeter --> 10 Meter (Check conversion ​here)
Independent Wheelbase of Vehicle: 1350 Millimeter --> 1.35 Meter (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
SVSAh = %ALr/((%Br)*(1/SVSAl)/(h/bind)) --> 2.74/((60.88889)*(1/0.6)/(10/1.35))
Evaluating ... ...
SVSAh = 0.199999996350365
STEP 3: Convert Result to Output's Unit
0.199999996350365 Meter -->199.999996350365 Millimeter (Check conversion ​here)
FINAL ANSWER
199.999996350365 200 Millimeter <-- Side View Swing Arm Height
(Calculation completed in 00.020 seconds)

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Anti Geometry of Independent Suspension Calculators

Wheelbase of Vehicle from Percentage Anti Dive
​ LaTeX ​ Go Independent Wheelbase of Vehicle = Percentage Anti Dive Front/((Percentage Front Braking)*(Side View Swing Arm Height/Side View Swing Arm Length)/(Height of CG above Road))
Height of Centre of Gravity from Road Surface from Percentage Anti Dive
​ LaTeX ​ Go Height of CG above Road = ((Percentage Front Braking)*(Side View Swing Arm Height/Side View Swing Arm Length)*Independent Wheelbase of Vehicle)/Percentage Anti Dive Front
Percentage Front Braking given Percentage Anti Dive
​ LaTeX ​ Go Percentage Front Braking = Percentage Anti Dive Front/((Side View Swing Arm Height/Side View Swing Arm Length)/(Height of CG above Road/Independent Wheelbase of Vehicle))
Percentage Anti Dive on Front
​ LaTeX ​ Go Percentage Anti Dive Front = (Percentage Front Braking)*(Side View Swing Arm Height/Side View Swing Arm Length)/(Height of CG above Road/Independent Wheelbase of Vehicle)

Side View Swing Arm Height given Percentage Anti Lift Formula

​LaTeX ​Go
Side View Swing Arm Height = Percentage Anti Lift/((Percentage Rear Braking)*(1/Side View Swing Arm Length)/(Height of CG above Road/Independent Wheelbase of Vehicle))
SVSAh = %ALr/((%Br)*(1/SVSAl)/(h/bind))

What are the Benefits of Anti Geometry?

Anti-geometries are being used on aero cars. This is because the angle of the underbody was very carefully designed to produce maximum downforce at the set angle. Therefore any changes in the height of the floor pan front to rear would disrupt downforce and therefore massively reduce the grip of the car. With 100% anti-geometry installed it meant that on throttle or brakes the bottom of the car would not pivot and therefore maximum aerodynamic grip was available from the car. Another reason is due to the fact that most race cars have a very low ride height and have an increased chance of bottoming out on circuit. If a car bottoms out on circuit then the suspension suddenly becomes void, the car is slowed down by the increased friction and damage can occur to the underside of the car and any underbody aero. With some anti geometry installed it provides a limiting factor to how much the car can physically dive or squat in accelerating or braking conditions making it very difficult for the car to bottom out.

What are the Negatives of Anti Geometry?

The main drawback to anti-geometry is driver feedback. When a driver applies the brakes in a car they expect the front of the car to dip down. The more severe the dip, the harder they are on the brakes. When they apply the throttle they would also expect the back of the car to sit down slightly. The more the back sits down, the harder they are accelerating. Anti-geometry removes this sensation and provides the driver will very little dynamic feedback under these conditions leaving them feeling only the G forces from their actions. This can be difficult to drive and also difficult to anticipate reaching the limits of grip during braking and acceleration causing an unsettled car. Therefore it is often best to design some squat and some dive back into the suspension system and not run 100% anti-geometry unless the aero dynamics dictate so.

How to Calculate Side View Swing Arm Height given Percentage Anti Lift?

Side View Swing Arm Height given Percentage Anti Lift calculator uses Side View Swing Arm Height = Percentage Anti Lift/((Percentage Rear Braking)*(1/Side View Swing Arm Length)/(Height of CG above Road/Independent Wheelbase of Vehicle)) to calculate the Side View Swing Arm Height, Side View Swing Arm Height given Percentage Anti Lift formula is defined as a measure of the height of the swing arm in a vehicle's suspension system, which is influenced by the percentage of anti-lift and other factors, providing a critical parameter for vehicle design and stability analysis. Side View Swing Arm Height is denoted by SVSAh symbol.

How to calculate Side View Swing Arm Height given Percentage Anti Lift using this online calculator? To use this online calculator for Side View Swing Arm Height given Percentage Anti Lift, enter Percentage Anti Lift (%ALr), Percentage Rear Braking (%Br), Side View Swing Arm Length (SVSAl), Height of CG above Road (h) & Independent Wheelbase of Vehicle (bind) and hit the calculate button. Here is how the Side View Swing Arm Height given Percentage Anti Lift calculation can be explained with given input values -> 197080.3 = 2.74/((60.88889)*(1/0.6)/(10/1.35)).

FAQ

What is Side View Swing Arm Height given Percentage Anti Lift?
Side View Swing Arm Height given Percentage Anti Lift formula is defined as a measure of the height of the swing arm in a vehicle's suspension system, which is influenced by the percentage of anti-lift and other factors, providing a critical parameter for vehicle design and stability analysis and is represented as SVSAh = %ALr/((%Br)*(1/SVSAl)/(h/bind)) or Side View Swing Arm Height = Percentage Anti Lift/((Percentage Rear Braking)*(1/Side View Swing Arm Length)/(Height of CG above Road/Independent Wheelbase of Vehicle)). Percentage Anti Lift is the percentage of the weight transfer that is resisted by the suspension during acceleration or braking in an independent suspension system, Percentage Rear Braking is the proportion of braking force applied to the rear wheels in an independent suspension system to maintain vehicle stability and control, Side View Swing Arm Length is the distance from the axis of the coil spring to the axis of the wheel in an independent suspension system, Height of CG above Road is the vertical distance from the road surface to the centre of gravity of a vehicle's sprung mass & Independent Wheelbase of Vehicle is the distance between the center point of the front wheel and the center point of the rear wheel of a vehicle.
How to calculate Side View Swing Arm Height given Percentage Anti Lift?
Side View Swing Arm Height given Percentage Anti Lift formula is defined as a measure of the height of the swing arm in a vehicle's suspension system, which is influenced by the percentage of anti-lift and other factors, providing a critical parameter for vehicle design and stability analysis is calculated using Side View Swing Arm Height = Percentage Anti Lift/((Percentage Rear Braking)*(1/Side View Swing Arm Length)/(Height of CG above Road/Independent Wheelbase of Vehicle)). To calculate Side View Swing Arm Height given Percentage Anti Lift, you need Percentage Anti Lift (%ALr), Percentage Rear Braking (%Br), Side View Swing Arm Length (SVSAl), Height of CG above Road (h) & Independent Wheelbase of Vehicle (bind). With our tool, you need to enter the respective value for Percentage Anti Lift, Percentage Rear Braking, Side View Swing Arm Length, Height of CG above Road & Independent Wheelbase of Vehicle and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Side View Swing Arm Height?
In this formula, Side View Swing Arm Height uses Percentage Anti Lift, Percentage Rear Braking, Side View Swing Arm Length, Height of CG above Road & Independent Wheelbase of Vehicle. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Side View Swing Arm Height = Percentage Anti Dive Front/((Percentage Front Braking)*(1/Side View Swing Arm Length)/(Height of CG above Road/Independent Wheelbase of Vehicle))
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