Methods and systems for a steer-by-wire system with sensor devices

What is claimed is: 1 . An Electric Power Steering (EPS) system for a vehicle having a vehicle body having one or more wheels with an angled axis of rotation relative to the vehicle body, and having a drive assembly that causes a motor to generate power to rotate an output motor shaft, the rotational force converted to move a rack bar in a linear, axial direction, the EPS system comprising: a plurality of sensors integrated within the EPS system configured to sense a plurality of input signals based on characteristics of the vehicle; a drive belt coupled to the output motor shaft and a ball nut assembly, such that the drive belt transmits rotary motion to a cylindrical pulley coupled to the ball nut assembly, wherein the rotary motion causes a plurality of balls within the ball nut assembly to move the rack bar, such that the rack bar moves along a linear, axial direction; one or more sensors of the plurality of sensors integrated within the ball nut assembly such that the one or more sensors sense a ball nut assembly angle as one of the plurality of input signals; and in response to the rack bar moving along the linear, axial direction, alter the angled axis of the one or more wheels relative to the vehicle body to an extent determined based on the sensed input signals. 2 . The EPS system of claim 1 , wherein the one or more sensors are configured to transmit the one or more ball nut angles such that the one or more ball nut angles provide steer angle information to accurately determine the extent of rack bar linear motion required based on the amount of rotary motion of the steering wheel. 3 . The EPS system of claim 2 , wherein the at least one or more ball nut angles are used to determine sufficient rack bar linear movement, to the extent determined based on a rotary motion of a steering wheel and the sensed input signals without a pinion shaft. 4 . The EPS system of claim 1 , wherein the plurality of sensors include one or more motor position sensors configured to monitor and transmit motor portion information as at least one of the sensed input signals. 5 . The EPS system of claim 1 , wherein the plurality of sensors include a steering wheel angle sensor configured to monitor and transmit steering wheel angle information and a steering wheel torque sensor configured to monitor and transmit steering wheel torque information, based on the rotary motion of the steering wheel. 6 . The EPS system of claim 5 , wherein at least the steering wheel angle information and steering wheel torque information are used to determine an amount of rack bar linear motion distance required and an amount of torque required by the EPP for sufficient rack bar linear motion, respectively, based on the rotary motion of the steering wheel. 7 . The EPS system of claim 1 , wherein the plurality of sensors is of at least one of a Hall Effect, Magneto-Resistance or Giant Magneto-Resistance type sensor. 8 . The EPS system of claim 1 , wherein one or more tie rod force transducers, integrated with one or more tie rods coupled with the rack bar, may be configured to monitor and transmit rack load information or a required amount of steering wheel torque information as at least one of the sensed input signals, wherein at least said information is used to estimate rack force calculations of the EPS system. 9 . A steering system comprising: a steering feedback module (SFM) comprising: an SFM motor and one or more SFM sensors associated with the SFM, wherein the SFM sensors are configured to sense one or more SFM input signals based on a rotary motion input of a steering wheel, and a first electronic control unit (ECU) to control the SFM and the one or more SFM input signals; an electric power steering system (EPS) comprising: one or more EPS sensors associated with the EPS, wherein the EPS sensors are configured to sense one or more EPS input signals based on characteristics of a vehicle, an EPS motor configured to provide power to an output motor shaft for rotary movement and integrated with at least one of the EPS sensors to sense an EPS motor position, wherein at least one of the EPS input signals includes the EPS motor position, a ball nut assembly integrated with at least one of the EPS sensors configured to sense a ball nut angle of the ball nut assembly, wherein at least one of the EPS input signals includes the ball nut angle, a rack bar, wherein the rack bar moves about a linear axis actuated by a drive assembly, the drive assembly including a drive belt coupled to the output motor shaft and the ball nut assembly such that the drive belt transmits rotary motion, by rotary movement of the output shaft, to a cylindrical pulley coupled to the ball nut assembly and further transmits rotary motion to the ball nut assembly, and a second ECU to control the EPS and the one or more EPS input signals, wherein the first ECU and second ECU are communicatively coupled; and the first ECU transmits a signal to the second ECU, in response to the rotary motion input of the steering wheel, to activate the drive assembly, wherein the rack bar and angles of one or more wheels, coupled to the rack bar of the vehicle, are altered to a determined extent based on the SFM input signals and EPS input signals. 10 . The steering system of claim 9 , wherein at least the ball nut angle and the EPS motor position are used to determine the extent of rack bar linear motion without a pinion shaft. 11 . The steering system of claim 9 , wherein at least the ball nut angle and the motor position are used to determine a sufficient steering speed to the determined extent based on the SFM input signals and EPS input signals without a pinion shaft. 12 . The steering system of claim 9 , wherein the one or more SFM input signals based on the rotary motion input of the steering wheel include at least one of a motor position information, steering wheel torque information and steering wheel angle information. 13 . A method for accurately altering steering wheel angles of a vehicle comprising: sensing, by a plurality of sensors, one or more input signals based on a plurality of vehicle characteristics wherein the plurality of sensors are associated with a steer-by-wire system, wherein one or more sensors of the plurality of sensors are sensing a ball nut angle within a ball nut assembly as one of the plurality of input signals; determining a plurality of steering characteristics based on the one or more input signals; actuating, by a drive assembly, linear motion of a rack bar based on the determined plurality of steering characteristics such that one or more wheel angles of the vehicle are altered. 14 . The method of claim 13 , further comprising: sensing the ball nut angle includes providing steer angle information to accurately determine at least one of a required amount of rack bar linear motion, steering speed and torque required for rack bar linear motion actuated by the drive assembly. 15 . The method of claim 13 , further comprising: determining a plurality of steering characteristics includes at least one of a required amount of rack bar linear motion, steering speed and torque required for rack bar linear motion, actuated by the drive assembly. without a pinion shaft. 16 . The method of claim 13 , wherein sensing one or more input signals based on characteristics of the vehicle include at least one characteristic from the rotary motion of the steering wheel including steering wheel torque information, steering wheel angle information and motor position information, wherein said information is sensed by at least one