Inductive load driver slew rate controller

What is claimed is: 1. An integrated circuit for driving a first load switch wherein the first load switch powers a current load, the integrated circuit comprising: a first digital slew-rate control unit for generating first control signals comprising a first digital logic gate receiving a feedback signal from the current load through a series connected first capacitor and first resistor wherein a node between the first resistor and the first capacitor is coupled with an input of the first digital logic gate, wherein the first digital slew-rate control unit generates the first control signals based on the feedback signal that indicates the rate of voltage change on the current load; and a first driver operated by the first control signals, wherein the first driver generates a slew-rate controlled output signal that operates the first load switch, wherein the first driver is modulated to generate the slew-rate controlled output signal during state transitions of the first load switch, wherein the modulation performs discrete slew-rate adjustments. 2. The integrated circuit of claim 1 , wherein the first load switch is a MOSFET. 3. The integrated circuit of claim 1 , further comprising a second driver that generates a constant output, wherein the first load switch is operated by the first driver and the second driver, and wherein the second driver generates a constant output during steady states of the first switch. 4. The integrated circuit of claim 3 , wherein the first driver is a large low impedance driver and the second driver is a small current limited driver. 5. The integrated circuit of claim 3 , wherein the first load switch is a low-side load switch and the integrated circuit further comprises: a second digital slew-rate control unit for generating second control signals comprising a second digital logic gate receiving the feedback signal from the current load through a series connected second resistor and second capacitor wherein a node between the second resistor and the second capacitor is coupled with an input of the second digital logic gate, wherein the second digital slew-rate control unit receives a second input signal and generates the second control signals based on the second input signal and the feedback signal that indicates the rate of voltage change on the load; and a third driver operated by the second control signals, wherein the third driver generates a slew-rate controlled output signal that operates the second load switch, a fourth driver that generates a constant output, wherein the second load switch is operated by the third driver and the fourth driver, and wherein the fourth driver generates a constant output during steady states of the second load switch, and wherein the third driver is modulated to generate a slew-rate controlled output during state transitions of the second load switch, wherein the third and fourth drivers are a high-side drivers. 6. The integrated circuit of claim 5 , wherein the series connected second resistor and second capacitor are coupled between the load and a power supply. 7. The integrated circuit of claim 1 , wherein the series connected first capacitor and first resistor are coupled between the load and a power supply common. 8. The integrated circuit of claim 7 , wherein the first digital logic gate is a NOR gate and the first digital slew-rate control unit further comprises: a NAND gate having a first input receiving the feedback signal and a second input receiving an input voltage signal, wherein the output of the NAND gate controls a p-channel field-effect transistor of the first driver; and wherein a first input of the NOR gate receives the feedback signal through said series connected first resistor and first capacitor and a second input receives the input voltage signal, wherein the output of the NOR gate controls an n-channel field-effect transistor of the first driver, wherein the p-channel field-effect transistor and the n-channel field-effect transistor are coupled in series and a node between the p-channel field-effect transistor and the n-channel field-effect transistor provides an output of the first driver. 9. The integrated circuit of claim 1 , wherein the modulation is performed by a digital output signal of the first digital slew-rate control unit such that there are periods where a voltage at the gate of the first load switch does not increase or decrease mixed with periods where voltage at the gate of the first load switch increases or decreases. 10. A slew-rate controlled load driving system comprising: a first load switch for powering a current load; a first digital slew-rate control unit that generates control signals, wherein the control signals are generated based on a feedback signal that indicates the rate of voltage change on the current load, wherein the feedback signal is fed to the first digital slew-rate control unit through a first capacitor and first resistor connected in series between the current load and a power supply common; and a first load driver circuit operated by the control signals, wherein the first load driver circuit generates a modulated slew-rate controlled output voltage that operates the first load switch during state transitions of the first load switch, wherein the modulation is performed by a digital output signal of the first digital slew-rate control unit which comprises periods where no voltage increases or decreases at the gate of the first load switch are made mixed with periods where voltage increases or decreases at the gate of the first load switch are made. 11. The system of claim 10 , wherein the first load switch is a MOSFET. 12. The system of claim 11 , wherein the first digital slew-rate control unit and the first load driver circuit form a slew-rate control driver; and the system further comprises: a non-control driver that generates a constant output, wherein the load switch is operated by the non-control driver and the slew-rate control driver, and wherein the slew-rate control driver generates a constant output during steady states of the load switch, and wherein the slew-rate control driver is pulse width modulated to generate the modulated slew-rate controlled output during state transitions of the first load switch. 13. The system of claim 12 , wherein the slew-rate controlled driver is a large low impedance driver and the non-control driver is a small current limited driver. 14. The system of claim 10 , wherein first digital slew-rate control unit and the first load driver circuit comprise a low-side driver, and the first load switch is a low-side load switch and the system further comprises: a second digital slew-rate control unit for generating high-side control signals, wherein the second digital slew-rate control unit generates the high-side control signals based on the feedback signal that indicates the rate of voltage change on the current load, wherein the feedback signal is fed to the second digital slew-rate control unit through a second resistor and second capacitor connected in series between the current load and a power supply; a second load driver circuit operated by the high-side control signals, wherein the second load driver circuit generates a slew-rate controlled output voltage that operates the second load switch, wherein the second load driver circuit and the second digital slew-rate control unit comprise a high-side driver. 15. The system of claim 10 , wherein the first digital slew-rate control unit further comprises: a NOR gate having a first input coupled with an input voltage and a second input coupled with a node between the first resistor and the fi