Feature-based level control using loudness growth functions

What is claimed is: 1. A sound processing device, comprising: one or more feature extractors configured to extract one or more features from a sound signal envelope; a controller configured to generate one or more control signals based on the one or more features; and a compressor configured to perform adaptive signal compression by applying a loudness growth function (LGF) to the envelope according to the one or more control signals to modify a level of the envelope and produce a compressed signal. 2. The sound processing device of claim 1 , wherein the compressed signal is a magnitude signal. 3. The sound processing device of claim 1 , wherein at least one of the one or more control signals generated by the controller indicates a base level of the loudness growth function when performing the adaptive signal compression, and wherein the compressor is configured to adapt the loudness growth function according to the base level signal. 4. The sound processing device of claim 1 , wherein at least one of the one or more control signals generated by the controller indicates a saturation level of the loudness growth function when performing the adaptive signal compression, and wherein the compressor is further configured to adapt the loudness growth function according to the saturation-level signal. 5. The sound processing device of claim 1 , wherein the controller is configured to generate a gain, and wherein the sound processing device further comprises: an amplifier configured to adaptively amplify the envelope according to the gain. 6. The sound processing device of claim 1 , wherein the sound processing device is a hearing prosthesis that comprises a microphone; one or more memories; and a processor operatively coupled to the microphone and the one or more memories, wherein the processor is configured to execute instructions stored in the one or more memories to implement the one or more feature extractors, the controller, and the compressor. 7. The sound processing device of claim 6 , wherein the envelope is derived from an input sound signal obtained from the microphone. 8. The sound processing device of claim 6 , wherein the processor is configured to adapt stimulation signals according to the one or more control signals, and wherein the hearing prosthesis further includes: stimulating circuitry configured to stimulate tissue of a recipient of the hearing prosthesis according to the stimulation signals. 9. The sound processing device of claim 8 , wherein the hearing prosthesis is a cochlear implant. 10. A sound processing device comprising: a set of feature-based regulators configured to produce a set of control signals from a set of envelopes, respectively; and a plurality of compressors configured to perform signal compression by adaptively applying loudness growth functions (LGFs) to the set of envelopes according to the set of control signals; wherein the set of control signals includes: a compressor-common control signal applicable to all of the compressors; and a plurality of compressor-specific control signals, where each of the plurality of compressor-specific control signals is applicable to only one of the plurality of compressors. 11. The sound processing device of claim 10 , wherein: the set of control signals includes a subset of saturation signals; and the device further comprises: selection logic configured to select the compressor-common control signal from amongst the subset of saturation signals. 12. The sound processing device of claim 11 , wherein: the set of feature-based regulators includes a subset of saturation-level regulators (FBR-Ss) configured to generate the subset of saturation signals from corresponding members of the set of envelopes, respectively. 13. The sound processing device of claim 12 , wherein the set of FBR-Ss includes one or more of: a fast FBR-S configured to generate a fast saturation signal; a slow FBR-S configured to generate a slow saturation signal; and a minimizing FBR-S configured to generate a minimum saturation level that is at least a desired amount greater than a corresponding base level. 14. The sound processing device of claim 13 , further comprising: a maxima selector configured to select the maximum-valued member from the set of envelopes; wherein each of the fast FBR-S and the slow FBR-S is further configured to operate on the maximum-valued member amongst the set of envelopes. 15. The sound processing device of claim 13 , wherein: the minimizing FBR-S is further configured to operate on a maximum-valued member of a set of base level signals. 16. The sound processing device of claim 10 , wherein: the set of feature-based regulators includes a subset of base-level regulators (FBR-Bs) configured to generate a set of base signals from corresponding members of the set of subject signals, respectively; and the set of base signals is the set of compressor-specific control signals. 17. The sound processing device of claim 10 , wherein the sound processing device is a hearing prosthesis that comprises: a microphone; one or more memories; and a processor, operatively coupled to the microphone and the one or more memories, wherein the processor is configured to execute instructions stored in the one or more memories to implement the one or more feature-based regulators and the compressors. 18. The sound processing device of claim 17 , wherein the processor is further configured to adapt stimulation signals according to the one or more control signals, and wherein the hearing prosthesis further includes: stimulating circuitry to stimulate tissue of a recipient of the hearing prosthesis according to the stimulation signals. 19. The sound processing device of claim 17 , wherein the envelope is derived from an input sound signal obtained at least indirectly from the microphone. 20. The sound processing device of claim 10 , wherein one or more of the compressors is a non-linear compressor.