Agricultural machine suspension control system

What is claimed is: 1. An agricultural machine comprising: a frame; a ground-engaging element; a suspension system that movably supports the frame relative to the ground-engaging element, wherein the suspension system comprises an air spring, having a flexible sidewall, configured to apply, for a given displacement of the frame relative to the ground-engaging element, a force based on a force-to-displacement relationship; and a control system configured to: receive an input indicative of an operational state of the agricultural machine during operation on a terrain; and automatically control the suspension system to adjust the force-to-displacement relationship by changing a configuration of the air spring, having the flexible sidewall, to adjust the force-to-displacement relationship of the air spring from a first force-to-displacement relationship to a second force-to-displacement relationship that is different than the first force-to-displacement relationship based on the operational state, wherein changing the configuration of the air spring comprises controlling a switching valve to select a selected control valve from one of a first control valve or a second control valve, wherein the selected control valve controls a flow of pressurized air to the air spring. 2. The agricultural machine of claim 1 , wherein the input comprises geo-referenced terrain data indicative of terrain characteristics of the terrain. 3. The agricultural machine of claim 1 , wherein the agricultural machine comprises an agricultural sprayer including a spraying system having a material tank configured to store a material to be sprayed and a set of spray nozzles and wherein the operational state is indicative of an amount of the material in the material tank. 4. The agricultural machine of claim 1 , wherein the control system is configured to adjust a spring rate of the air spring based on the operational state. 5. The agricultural machine of claim 1 , wherein the operational state comprises at least one of an environmental condition or a machine configuration. 6. The agricultural machine of claim 5 , wherein the input comprises in situ data generated based on a sensor signal received during the operation of the agricultural machine. 7. The agricultural machine of claim 6 , wherein the sensor signal is generated by an environment sensor associated with the agricultural machine. 8. The agricultural machine of claim 6 , wherein the sensor signal represents at least one of an attitude of the agricultural machine or a geographic location of the agricultural machine. 9. The agricultural machine of claim 6 , wherein the sensor signal represents a configuration of a controllable subsystem of the agricultural machine. 10. The agricultural machine of claim 1 , wherein the input comprises a priori data generated prior to the operation of the agricultural machine on the terrain. 11. A method of controlling an agricultural machine, the method comprising: detecting an operational state of the agricultural machine during an operation on a terrain, the agricultural machine comprising a suspension system, including a first control valve, a second control valve, a switching valve, and an air spring, having a flexible sidewall, that movably supports a frame relative to a ground-engaging element and is configured to apply, for a given displacement of the frame relative to the ground-engaging element, a force based on a force-to-displacement relationship; determining an adjustment of the suspension system from a first force-to-displacement relationship to a second force-to-displacement relationship, that is different than the first force-to-displacement relationship, based on the operational state; and controlling the switching valve to select a selected control valve, from one of the first control valve or the second control valve, that controls a flow of pressurized air to the air spring, having the flexible sidewall, based on the determined adjustment. 12. The method of claim 11 , wherein receiving the operational state comprises receiving geo-referenced terrain data indicative of terrain characteristics of the terrain. 13. The method of claim 11 , wherein controlling the air spring comprises adjusting a spring rate of the air spring based on the operational state. 14. The method of claim 11 , wherein receiving the operational state comprises receiving a sensor signal generated by an environment sensor associated with the agricultural machine. 15. The method of claim 11 , wherein receiving the operational state comprises receiving a sensor signal representing a configuration of a controllable subsystem of the agricultural machine. 16. A suspension system for an agricultural machine, the suspension system comprising: an air spring, having a flexible sidewall, configured to support a frame of the agricultural machine relative to a ground engaging element by applying a force against the frame at a spring rate of the air spring; and a controller configured to: receive terrain data representing terrain characteristics; and based on the terrain data, automatically control the air spring to adjust the spring rate of the air spring by controlling a switching valve to select a selected control valve from one of a first control valve or a second control valve, wherein the selected control valve controls a flow of pressurized air to the air spring. 17. The suspension system of claim 16 , wherein the agricultural machine comprises an agricultural sprayer including a spraying system having a material tank configured to store a material to be sprayed and a set of spray nozzles, the air spring has a first spring rate at a first ride height, and the controller is configured to adjust the air spring to a second spring rate by changing the first ride height to a second ride height.