System for retrofitting vehicle automation

We claim: 1. An autonomous vehicle retrofit system comprising: a central computer; and a braking interface configured to decelerate a wheel of a vehicle via actuation of a brake caliper, the braking interface comprising: a brake pedal, a first master cylinder assembly mechanically coupled between the brake pedal and the brake caliper such that actuation of the brake pedal causes actuation of the first master cylinder assembly; a first hydraulic brake line hydraulically coupled to the first master cylinder assembly such that actuation of the first master cylinder assembly causes an increase in hydraulic fluid pressure in the first hydraulic brake line; a second master cylinder assembly coupled between the central computer and the brake caliper such that the central computer controls actuation of the second master cylinder assembly; a second hydraulic brake line hydraulically coupled to the second master cylinder assembly such that actuation of the second master cylinder assembly causes an increase in hydraulic fluid pressure in the second hydraulic brake line; and an actuator selector hydraulically coupled to the brake caliper, further hydraulically coupled to the first hydraulic brake line and to the second hydraulic brake line, that selectively actuates the brake caliper in response to actuation of at least one of the first master cylinder assembly and the second master cylinder assembly; wherein selective actuation is determined by hydraulic fluid pressures of the first and second hydraulic brake lines a pedal sensor, detectably coupled to the brake pedal and communicatively coupled to the central computer; wherein the pedal sensor monitors a condition of the brake pedal and communicates pedal sensor data based on the condition of the brake pedal to the central computer; wherein the central computer controls the second master cylinder assembly based on the pedal sensor data, wherein the pedal sensor data comprises a change in a position of the brake pedal per unit time; wherein the central computer controlling the second master cylinder based on the pedal sensor data comprises the central computer actuating the second master cylinder to perform emergency braking based on the change in the position of the brake pedal per unit time exceeding a threshold brake pedal rate. 2. The autonomous vehicle retrofit system of claim 1 , wherein the actuator selector further comprises a one-way check valve, fluidly coupling both of the first hydraulic brake line and the second hydraulic brake line to a brake fluid reservoir; wherein the check valve allows brake fluid to flow from the brake fluid reservoir to the first and second hydraulic brake lines; wherein the check valve prevents brake fluid from flowing from the first and second hydraulic brake lines to the brake fluid reservoir. 3. The autonomous vehicle retrofit system of claim 1 , wherein the pedal sensor comprises a pedal pressure sensor; wherein pedal sensor data comprises surface pressure on a surface of the brake pedal; wherein controlling the second master cylinder based on the pedal sensor data comprises the central computer actuating the second master cylinder to perform emergency braking based on the surface pressure on the surface of the brake pedal exceeding a threshold surface pressure. 4. An autonomous vehicle retrofit system comprising: a central computer; a braking interface configured to decelerate a wheel of a vehicle via actuation of a brake caliper, comprising: a brake pedal, a first master cylinder assembly mechanically coupled between the brake pedal and the brake caliper such that actuation of the brake pedal causes actuation of the first master cylinder assembly; a first hydraulic brake line hydraulically coupled to the first master cylinder assembly such that actuation of the first master cylinder assembly causes an increase in hydraulic fluid pressure in the first hydraulic brake line; a second master cylinder assembly coupled between the central computer and the brake caliper such that the central computer controls actuation of the second master cylinder assembly; a second hydraulic brake line hydraulically coupled to the second master cylinder assembly such that actuation of the second master cylinder assembly causes an increase in hydraulic fluid pressure in the second hydraulic brake line; and an actuator selector hydraulically coupled to the brake caliper, further hydraulically coupled to the first hydraulic brake line and to the second hydraulic brake line, that selectively actuates the brake caliper in response to actuation of at least one of the first master cylinder assembly and the second master cylinder assembly; wherein selective actuation is determined by hydraulic fluid pressures of the first and second hydraulic brake lines; and a steering interface, the steering interface comprising: three steering motors, mechanically coupled to a steering column of the vehicle; wherein the three steering motors control the steering of the vehicle by applying a torque to the steering column; wherein any two steering motors of the three steering motors have a greater maximum power output than the maximum power output of the third steering motor; wherein the steering column is further coupled to a steering wheel; wherein the steering column rotates in response to either of manual rotation of the steering wheel and actuation of the three steering motors by the central computer; a steering position sensor, communicatively coupled to the central computer; wherein the steering position sensor monitors a condition of a first steering motor of the three steering motors and communicates steering position sensor data based on the condition of the first steering motor to the central computer; and a sensor suite, communicatively coupled to the central computer; wherein the sensor suite monitors a condition of the driving environment and communicates sensor suite data based on the condition of the driving environment to the central computer; wherein the central computer controls the three steering motors based on the sensor suite data; and a user intervention sensor that measures an actual rotational speed of the first steering motor; wherein the sensor suite data comprises accelerometer data; wherein the central computer detects attempted user steering intervention by calculating an estimated rotational speed of the first steering motor and comparing the estimated rotational speed to the actual rotational speed. 5. The autonomous vehicle retrofit system of claim 4 , wherein the central computer modifies operation of the three steering motors in response to detected user steering intervention. 6. The autonomous vehicle retrofit system of claim 4 , further comprising a second steering position sensor detectably coupled to the steering column and communicatively coupled to the central computer; wherein the second steering position sensor monitors a condition of the steering column and communicates a second set of steering position sensor data based on the condition of the steering column to the central computer; wherein the central computer calculates an inferred torsion of the steering column from a difference of the steering position sensor data and the second set of steering position sensor data and detects attempted user steering intervention based on the inferred torsion. 7. The autonomous vehicle retrofit system of claim 4 , further comprising a strain sensor, detectably coupled to the steering column and communicatively coupled to the central computer; wherein the strain sensor monitors strain of the steering column; wherein the central computer modifies operation of the three steering motors in response to the monitored strain of the steering column. 8. An autonomous vehicle retr