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Steering System

Steering system for Ackerman and rack-and-pinion steering mechanisms

Since R2022b

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  • Steering System block

Libraries:
Vehicle Dynamics Blockset / Steering

Description

The Steering System block implements dynamic steering to calculate the wheel steer angles for rack-and-pinion mechanisms with friction, compliance, and Ackerman steering features. The block uses the steering wheel input angle or torque input, vehicle speed, caster angle, and right and left wheel feedbacks to calculate the wheel steer angles. The block uses the vehicle coordinate system.

If you select the Power assist parameter, you can specify a torque assist lookup table that is a function of the vehicle speed and steering wheel input torque. The block uses the steering wheel input torque and torque assist to calculate the steering dynamics. If you select the Ackerman steering parameter, you can specify a lookup table of percentage Ackerman values to calculate the Ackerman steering effects, or a constant Ackerman percentage, where 100 percent means perfect Ackerman steering.

If you select the Power assist, Ackerman steering, or Kingpin moment parameters in the Input signals section, you can specify additional inputs for the external power assist torques, percent Ackerman values, or kingpin moments.

Use the Steered axle parameter to specify whether the front or rear axle is steered.

SettingImplementation
Front

Front axle steering

Figure of front steering turning right

Rear

Rear axle steering

Figure of rear steering turning right

Steering

Rack-and-Pinion

For rack-and-pinion steering, pinion rotation causes linear motion of the rack, which steers the wheels through the tie rods and steering arms.

Figure of rack, rod, and arm in rack and pinion steering mechanism

Figure of rod in rack and pinion steering mechanism

To calculate the steered wheel angles, the block uses these equations.

l1=TWlrack2ΔPl22=l12+D2ΔP=rδinβ=π2tan1[Dl1]cos1[larm2+l22lrod22larml2]

The illustration and equations use these variables.

δin

Pinion angle (steering shaft angle into pinion)

δL

Left wheel steer angle

δR

Right wheel steer angle

TW

Track width

r

Pinion radius

ΔP

Linear change in rack position from "straight ahead" position

D

Longitudinal distance between rack and steered axle

lrack

Rack length (distance between inner tie-rod ends)

larm

Steering arm length

lrod

Tie rod length

Ackerman Steering

For 100% (ideal) Ackerman steering, all wheels follow circular arcs with the same center point.

Figure of Ackerman steering turning right around turning circle

To calculate the steered wheel angles, the Ackerman block uses these equations:

cot(δL)cot(δR)=TWWBδAck=δinγδL=tan1(WBtan(δAck)WB+0.5TWtan(δAck))δR=tan1(WBtan(δAck)WB0.5TWtan(δAck))

Definition of variables used:

δin

Pinion angle (steering shaft angle into pinion)

δL

Left wheel steer angle

δR

Right wheel steer angle

δAck

Ackerman steer angle

TW

Track width

WB

Wheel base

γ

Steering ratio: Ratio of pinion angle to Ackerman angle

Examples

Double Lane Change Reference Application

Double Lane Change Reference Application

Simulate a full vehicle dynamics model undergoing a double lane change maneuver standard ISO 3888-2. Use for vehicle dynamics ride and handling analysis and chassis controls development, including yaw stability and lateral acceleration limits.

Open Example

Ports

Input

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Vehicle speed, v, in m/s, specified as a scalar. This is the magnitude of the vehicle CG longitudinal velocity vector.

Wheel caster angle, τL, in radians, specified as a 1-by-2 vector. The first element is the angle for the left wheel and the second is the angle for the right wheel.

Dependencies

To enable this port, clear Input signals > Kingpin moment.

Wheel steer angle feedback, in radians, specified as a 1-by-2 vector. The first element is the angle feedback from the left wheel and the second element is the angle feedback from the right wheel.

Dependencies

To enable this port, clear Input signals > Kingpin moment.

Steering wheel angle input from driver, in radians, specified as a scalar.

Dependencies

To enable this port, select Steering inputs > Angle.

Steering wheel torque input from driver, in N*m, specified as a scalar.

Dependencies

To enable this port, select Steering inputs > Torque.

The torque value of power assist on the steering shaft, in N*m, specified as a scalar. Supplied externally into this port.

Dependencies

To enable this port, select Input signals > Power assist.

The Ackerman value in percent, specified as a scalar. Supplied externally into this port.

Dependencies

To enable this port, select Input signals > Ackerman steering.

Tire forces and moments feedback from both right and left tires, specified as a 1-by-12 vector that contains the following values, in order:

DescriptionUnit
x-directional Force, LeftN
x-directional Force, RightN
y-directional Force, LeftN
y-directional Force, RightN
z-directional Force, LeftN
z-directional Force, RightN
x-directional Moment, LeftN*m
x-directional Moment, RightN*m
y-directional Moment, LeftN*m
y-directional Moment, RightN*m
z-directional Moment, LeftN*m
z-directional Moment, RightN*m

Dependencies

To enable this port, clear Input signals > Kingpin moment.

Left kingpin moment, in N*m, specified as a scalar.

Dependencies

To enable this port, select Input signals > Kingpin moment.

Right kingpin moment, in N*m, specified as a scalar.

Dependencies

To enable this port, select Input signals > Kingpin moment.

Output

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Vehicle dynamics information, returned as a bus signal that contains the following:

SignalDescriptionUnit

StrWhlAngFdk

Steering wheel angle

rad

AstTrq

Torque applied by power assist

N·m

AstPwr

Power applied by power assist

W

LftTieRodForce

Axial force in left tie rod

N

RghtTieRodForce

Axial force in right tie rod

N

LftKpM

Left kingpin moment

N·m

RghtKpM

Right kingpin moment

N·m

LftWhlAng

Left wheel steer angle

rad

RghtWhlAng

Right wheel steer angle

rad

LftWhlSpd

Left wheel steer angle velocity

rad/s

RghtWhlSpd

Right wheel steer angle velocity

rad/s

TrqIn

Torque applied by driver on steering wheel

N·m

Left wheel steer angle, δL, in radians, returned as a scalar.

Right wheel steer angle, δR, in radians, returned as a scalar.

Parameters

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Block Options

Steering type for the Steering System.

Whether to model the intermediate shaft type using single or double Cardan joints.

Select to model power assist within the Steering System.

Dependencies

To enable this parameter, in the Input signals section, clear Power assist.

Select to set Ackerman steering percentage within the Steering System block.

Dependencies

To enable this parameter, in the Input signals section, clear Ackerman steering.

Input Signals

Select this parameter to enable the PwrAstTrq port.

Select this parameter to enable the PctAck port.

Select this parameter to enable the LftKpM and RghtKpM ports.

Select either the front or rear axle as the location of the Steering System.

This selection enables either the AngIn or TrqIn port as the driver input.

General

Track width, TW, in m, specified as a scalar.

Steering wheel angle from straight-ahead to either left or right lock, in rad, specified as a scalar. This causes both steered wheels to remain within their designed steering range.

The steering wheel deadband angle, in radians, from left-engagement to right-engagement.

Steering wheel moment of inertia, in kg*m2, specified as a scalar.

Steering shaft moment of inertia, in kg*m2, specified as a scalar.

Kingpin offset, in m, specified as a scalar.

Kingpin inclination angle, in rad, specified as a scalar.

Hub lead, in m, specified as a scalar.

Static loaded tire radius, in m, specified as a scalar.

Overall steering ratio, specified as a scalar.

Steering wheel angle breakpoints, in rad, specified as a 1-by-11 vector. Is used to parameterize either Ackerman value or rack gain.

Dependencies

To enable this parameter, set one of these parameters to Lookup table:

  • Rack and pinion > Rack gain parameterized by

  • Ackerman steering > Percent Ackerman parameterized by

Caster angle, in rad, specified as a scalar.

Dependencies

To enable this parameter, select Input signals > Kingpin moment.

Rack and Pinion

Whether to parameterize the rack gain as a constant value or by using a lookup table.

Rack gain, in m/rev, specified as a scalar.

Dependencies

To enable this parameter, set Rack gain parameterized by to Constant.

Rack gain table, in m/rev, specified as a 1-by-11 vector.

Dependencies

To enable this parameter, set Rack gain parameterized by to Lookup table.

Steering arm length, in m, specified as a scalar.

Rack length (distance between inner tie rod ends), in m, specified as a scalar.

Tie rod length, lrod, in m, specified as a scalar.

Longitudinal distance between the steered axle and rack centerline, D, in m, specified as a scalar.

Efficiency of the rack and pinion mechanism, ɛ, specified as a scalar.

Pinion inertia, in kg*m2, specified as a scalar.

Single Cardan Joint

Spatial angle for the single Cardan joint, in rad, specified as a scalar.

Dependencies

To enable this parameter, set Intermediate shaft type to Single Cardan joint.

Double Cardan Joints

Spatial angle for the upper Cardan joint, in rad, specified as a scalar.

Dependencies

To enable this parameter, set Intermediate shaft type to Double Cardan joints.

Spatial angle for the lower Cardan joint, in rad, specified as a scalar.

Dependencies

To enable this parameter, set Intermediate shaft type to Double Cardan joints.

Edge view angle between the planes of the two joints, in rad, specified as a scalar.

Dependencies

To enable this parameter, set Intermediate shaft type to Double Cardan joints.

Rotation phase angle between the two joints, in rad, specified as a scalar.

Dependencies

To enable this parameter, set Intermediate shaft type to Double Cardan joints.

Power Assist

Steering wheel torque breakpoints, in N·m, specified as a 1-by-M vector.

Dependencies

To enable this parameter, select the Power assist Block Option.

Vehicle speed breakpoints, in m/s, specified as a 1-by-N vector.

Dependencies

To enable this parameter, select the Power assist Block Option.

Torque assist table, ƒtrq, in N·m, specified as an M-by-N matrix.

The torque assist lookup table is a function of the vehicle speed, v, and steering wheel input torque, τin:

τast=ftrq(v,τin).

The block applies the steering wheel input torque and torque assist to the pinion.

Dependencies

To enable this parameter, select the Power assist Block Option.

Torque assist limit, in N·m, specified as a scalar.

Dependencies

To enable this parameter, select the Power assist Block Option.

Assist power limit, in watts, specified as a scalar.

Dependencies

To enable this parameter, select the Power assist Block Option.

Torque assist efficiency, specified as a scalar.

Dependencies

To enable this parameter, select the Power assist Block Option.

Cutoff frequency, in rad/s, specified as a scalar.

Dependencies

To enable this parameter, select the Power assist Block Option.

Ackerman Steering

Whether to parameterize the Ackerman values as a constant value or by a lookup table.

Dependencies

To enable this parameter, select the Ackerman steering Block Option.

Percent Ackerman, specified as a scalar.

Dependencies

To enable this parameter, select the Ackerman steering Block Option and set Percent Ackerman parameterized by to Constant.

Percent Ackerman table, specified as a 1-by-11 vector.

Dependencies

To enable this parameter, select the Ackerman steering Block Option and set Percent Ackerman parameterized by to Lookup table.

Friction and Compliance

Sealing stiffness, in N*m/rad, specified as a scalar.

Upper boundary friction, in N, specified as a scalar.

Pressure change due to friction boundary increase, in N/bar, specified as a scalar.

Maxwell element stiffness, in N*m/rad, specified as a scalar.

Maxwell element upper boundary friction, in N, specified as a scalar.

Maxwell linear damping coefficient, specified as a scalar.

Torsional stiffness of steering shaft, in N*m/rad, specified as a scalar.

Torsional viscous damping in steering shaft, in N*m*s/rad, specified as a scalar.

References

[1] Crolla, David, David Foster, et al. Encyclopedia of Automotive Engineering. Volume 4, Part 5 (Chassis Systems) and Part 6 (Electrical and Electronic Systems). Chichester, West Sussex, United Kingdom: John Wiley & Sons Ltd, 2015.

[2] Gillespie, Thomas. Fundamentals of Vehicle Dynamics. Warrendale, PA: Society of Automotive Engineers, 1992.

[3] Vehicle Dynamics Standards Committee. Vehicle Dynamics Terminology. SAE J670. Warrendale, PA: Society of Automotive Engineers, 2008.

Extended Capabilities

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.

Version History

Introduced in R2022b

See Also

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