Damper with digital valve

What is claimed is: 1. A shock absorber comprising: an intermediate tube; a pressure tube disposed within the intermediate tube and forming a working chamber within the pressure tube; a piston rod disposed within the pressure tube for axial movement within the working chamber; a piston assembly secured to the piston rod and moveable slidably within the pressure tube, the piston assembly dividing the working chamber into an upper working chamber and a lower working chamber; an intermediate chamber formed between the intermediate tube and the pressure tube, the intermediate chamber being in communication with the working chamber; a reserve tube disposed about at least a portion of the intermediate tube to form a reservoir chamber between the reserve tube and the intermediate tube; a base valve assembly disposed adjacent to the lower working chamber and controlling a flow of working fluid between the lower working chamber and the reservoir chamber; and the base valve assembly including a digital valve assembly in communication with the intermediate chamber and including a valve element moveable between a first position and a second position to control a flow of the working fluid from the intermediate chamber into the reservoir chamber, to help control damping provided by the shock absorber, wherein the base valve assembly includes a plurality of digital valve assemblies each in communication with the intermediate chamber and the reservoir chamber. 2. The shock absorber of 1 , wherein the digital valve assemblies are arranged radially about an axial centerline extending through the shock absorber. 3. The shock absorber of claim 1 , wherein the base valve assembly includes a valve body having a cylinder end port, and wherein at least one of the digital valve assemblies is disposed within the cylinder end port. 4. The shock absorber of claim 1 , wherein at least one of the digital valve assemblies includes: a sleeve; a spool forming the valve element and being movable slidably within the sleeve, the sleeve and the spool cooperatively forming at least one inlet in communication with the intermediate chamber and at least one outlet in communication with the reservoir chamber; and an electrically energizable coil for moving the spool between the first and second positions, one of the first and second positions permitting a greater flow of the working fluid between the inlet and the outlet than the other of the positions. 5. The shock absorber of claim 4 , wherein the base valve assembly includes a valve body having a cylinder end port, the cylinder end port helping to define an inlet flow path in communication with the inlet of the digital valve assembly and an outlet flow path in communication with the outlet of the digital valve assembly, the outlet flow path extending along only a portion of an axial length of the sleeve. 6. The shock absorber of claim 4 , further including a spring disposed axially between the coil and the spool for biasing the spool in a selected axial direction. 7. The shock absorber of claim 1 , wherein the digital valve assemblies are independently controllable. 8. The shock absorber of claim 1 , wherein the base valve assembly further comprises a compression valve assembly. 9. A shock absorber comprising: an intermediate tube; a pressure tube disposed within the intermediate tube and forming a working chamber within the pressure tube; a piston rod disposed within the pressure tube for axial movement within the working chamber; a piston assembly secured to the piston rod and moveable slidably within the pressure tube, the piston assembly dividing the working chamber into an upper working chamber and a lower working chamber; an intermediate chamber formed between the intermediate tube and the pressure tube, the intermediate chamber being in communication with the working chamber; a reserve tube disposed about at least a portion of the intermediate tube to form a reservoir chamber between the reserve tube and the intermediate tube; a base valve assembly disposed adjacent to the lower working chamber and controlling a flow of working fluid between the lower working chamber and the reservoir chamber; and the base valve assembly including a digital valve assembly in communication with the intermediate chamber and including a valve element moveable between a first position and a second position to control a flow of the working fluid from the intermediate chamber into the reservoir chamber, to help control damping provided by the shock absorber, wherein the base valve assembly includes a valve body having a cylinder end port, and wherein the digital valve is disposed within the cylinder end port, the base valve assembly including a plurality of cylinder end ports arranged radially about an axial centerline extending through the shock absorber, and wherein each one of the cylinder end ports includes a digital valve assembly disposed therein, each said digital valve assembly controlling a flow of the working fluid from the intermediate chamber into the reservoir chamber. 10. A shock absorber comprising: an intermediate tube; a pressure tube disposed within the intermediate tube and forming a working chamber within the pressure tube; a piston rod disposed within the pressure tube for axial movement within the working chamber; a piston assembly secured to the piston rod and moveable slidably within the pressure tube, the piston assembly dividing the working chamber into an upper working chamber and a lower working chamber; an intermediate chamber formed between said intermediate tube and the pressure tube, the intermediate chamber being in communication with the upper working chamber; a reserve tube disposed about at least a portion of the intermediate tube to form a reservoir chamber between the reserve tube and the intermediate tube; a base valve assembly disposed adjacent to the lower working chamber and controlling a flow of working fluid between the lower working chamber and the reservoir chamber; and the base valve assembly including a plurality of independently electrically energizable valves arranged radially about an axial center of the base valve assembly, for controlling a flow of a portion of the working fluid from the intermediate chamber into the reservoir chamber, to help control damping provided by the shock absorber. 11. The shock absorber of claim 10 , wherein the base valve assembly further comprises a valve body having a plurality of cylinder end ports arranged radially about the axial center of the base valve assembly, each of the cylinder end ports receiving one of the plurality of independently electrically energizable valves. 12. The shock absorber of claim 11 , wherein the plurality of independently electrically energizable valves comprises a plurality of independently electrically energizable digital valve assemblies, each of the digital valve assemblies including: a sleeve; a spool disposed for sliding movement within the sleeve, the sleeve and spool cooperating to define at least one inlet and at least one outlet; and a coil which is electrically energizable to move the spool linearly within the sleeve between first and second positions, wherein one of the first and second positions permits a greater flow of the working flow through the spool and sleeve than the other of the positions. 13. The shock absorber of claim 12 , wherein each of the digital valve assemblies has a first end and a second end, wherein the sleeve of each one of the digital valve assemblies helps to define an outlet flow path adjacent its respective said spool, and wherein the outlet flow path extends along a full length o