Double filter with pass-through and method for dynamically compensating for the inlet fluid contamination

What is claimed is: 1. A multiple fluid circuit spray device, comprising: a fluid oscillator circuit substrate or chip having an input end, at least first and second fluidic circuits defined in first and second sides, and an output end which is transverse to said first and second sides and a plane between said sides; said first side including a first filter subchamber having an upstream end and a downstream end and a first filter dividing the upstream end of said first filter subchamber from the downstream end of said first filter subchamber, with said upstream end being in registry with said input end to receive liquid from a source of pressurized fluid; said second side including a second filter subchamber having an upstream end and a downstream end and a second filter dividing the upstream end of said second filter subchamber from the downstream end of said second filter subchamber with said upstream end being in registry with said input end to receive liquid from a source of pressurized fluid; an inter-circuit transverse bypass lumen or liquid flow path positioned downstream of the first filter subchamber and downstream of the second filter subchamber; said first fluidic circuit having an inlet in communication with said first filter subchamber and with said inter-circuit transverse bypass lumen or liquid flow path, wherein said first fluidic circuit includes an outlet throat leading through an outlet orifice to ambient at said output end to generate a first spray of said fluid to ambient; and said second fluidic circuit having an inlet in communication with said second filter subchamber and with said inter-circuit transverse bypass lumen or liquid flow path, wherein said second fluidic circuit includes an outlet throat leading through an outlet orifice to ambient at said output end to generate a second spray of said fluid to ambient. 2. The multiple fluid circuit spray device of claim 1 , wherein said inter-circuit transverse bypass lumen or liquid flow path is configured as a rectangular or oval passage which has a lateral width which is symmetrical about a central axis and terminates in opposing lateral passage sides, and said first fluidic circuit is a multiple power nozzle oscillator having first and second power nozzle lumens or passages with power nozzle inlets which are equally spaced from opposing lateral passage sides of the inter-circuit transverse bypass lumen or liquid flow path. 3. The multiple fluid circuit spray device of claim 2 , wherein said second fluidic circuit is at least one of a reversing chamber oscillator, a multiple power nozzle oscillator, and a feedback oscillator. 4. The multiple fluid circuit spray device of claim 1 , further comprising a nozzle housing for enclosing said fluid oscillator circuit substrate or chip and including at least one fluid inlet port. 5. The multiple fluid circuit spray device of claim 4 wherein said at least one fluid inlet port simultaneously and continuously provides inlet fluid to said upstream ends of said first inlet and said second inlet, whereby inlet fluid flowing through said first or second filter subchambers may pass through said inter-circuit bypass lumen or liquid flow path and into said first or second fluidic circuits. 6. A method for maintaining a selected outlet spray pattern in a multi-outlet multiple fluid circuit spray device, comprising: providing a fluid oscillator circuit substrate or chip having an input end, first and second sides, and an output end which is transverse to said first and second sides and a plane between said sides; defining at least first and second fluidic circuits in said first and second sides, respectively; incorporating in said first fluidic circuit a first filter subchamber having an upstream end and a downstream end and a first filter dividing the upstream end of said first subchamber from the downstream end of said first filter subchamber, with said upstream end being in registry with said input end to receive liquid from a source of liquid; incorporating in said second fluidic circuit a second filter subchamber having an upstream end and a downstream end and a second filter dividing the upstream end of said second filter subchamber from the downstream end of said second filter subchamber, with said upstream end being in registry with said input end to receive liquid from said source of liquid; defining an inter-circuit transverse bypass lumen or liquid flow path positioned downstream of the first filter subchamber and downstream of the second filter subchamber; incorporating in said first side, an inlet in communication with said first filter subchamber and with said inter-circuit transverse bypass lumen or liquid flow path; and an outlet throat leading through an outlet orifice to ambient at said output end to spray said fluid to ambient; incorporating in said second side, an inlet in communication with said second filter subchamber and with said inter-circuit transverse bypass lumen or liquid flow path; and an outlet throat leading through an outlet orifice to ambient at said output end to spray said fluid to ambient; enclosing said fluid oscillator circuit substrate or chip in a housing having at least one fluid inlet port; and wherein said at least one fluid inlet port is configured to simultaneously provide inlet fluid to said upstream ends of said first and second filter subchambers, whereby inlet fluid flowing through said first or second filter subchambers may pass through said inter-circuit transverse bypass lumen or liquid flow path and into said first or second fluidic circuits. 7. The method of claim 6 , wherein the step of defining at least first and second fluidic circuits includes providing at least one of a reversing chamber oscillator, a multiple power nozzle oscillator, and a feedback oscillator. 8. The method of claim 6 , wherein said inter-circuit transverse bypass lumen or liquid flow path is configured as a rectangular or oval passage which has a lateral width which is symmetrical about a central axis and terminates in opposing lateral passage sides, and said first fluid circuit is a multiple power nozzle oscillator having first and second power nozzle lumens or passages with power nozzle inlets which are equally spaced from said opposing lateral passage sides of said inter-circuit transverse bypass lumen or liquid flow path. 9. The method of claim 8 , wherein, when said first filter is clogged, fluid flows through said inter-circuit transverse bypass lumen or liquid flow path from said second filter and flows substantially equally into said first and second power nozzle lumens or passages.