Complex impedance detection

What is claimed is: 1. A printhead comprising: a nozzle; a firing chamber fluidly coupled to the nozzle; a printing fluid slot fluidly coupled to the firing chamber; and a sensor to detect a plurality of complex impedance values of a printing fluid at the printhead over a plurality of alternating current frequencies; and a processor to receive the plurality of complex impedance values from the sensor and, based on the plurality of complex impedance values measured at different frequencies of the alternating current, create a printing fluid signature of the printing fluid in Fourier domain; wherein the sensor comprises two electrodes placed at the nozzle and spaced apart across an ejection opening of the nozzle. 2. The printhead of claim 1 , wherein the sensor comprises an electrode located within an ejection chamber of the printhead. 3. The printhead of claim 1 , wherein the sensor comprises an electrode coupled to an interior surface of the ink slot. 4. The printhead of claim 1 , further comprising a database containing signatures in the Fourier domain of different printing fluids based on measuring complex impedance values over a plurality of frequencies of an alternating current. 5. The printhead of claim 4 , wherein the processor is to compare the printing fluid signature with the signatures in the database to determine what printing fluid is at the printhead. 6. The printhead of claim 1 , wherein the sensor is to apply an increasing or decreasing series of frequencies of alternating current to the printing fluid over time. 7. A method of determining a printing fluid provided to a printhead, comprising: with a number of sensors, applying an alternating current at a plurality of frequencies over time to the printing fluid to receive a plurality of complex impedance values; transforming the plurality of complex impedance values into Fourier domain to create a printing fluid signature; and comparing the signature based on the plurality of complex impedance signals to a database of such signatures that correspond to different types of printing fluids to identify the printing fluid provided to the printhead; wherein the plurality of complex impedance values are detected within 20 μs after a fluid ejection process has commenced and fluid is pushed out of a nozzle of the printhead. 8. The method of claim 7 , further comprising using the comparison of the signature to the database to identify certain characteristics of the printing fluid. 9. The method of claim 8 , wherein comparing the signature based on the complex impedance signals in Fourier domain, comprises determining whether the printing fluid has lost a water component. 10. The method of claim 7 , wherein a first sensor is incorporated into an orifice layer of the printhead and comprises two electrodes spanning a first nozzle defined in the orifice layer. 11. The method of claim 7 , further comprising, by comparing the signature to the database, determining whether the printing fluid at the printhead comprises contaminants. 12. The method of claim 7 , further comprising applying an increasing or decreasing series of frequencies of alternating current to the printing fluid over time while generating the plurality of complex impedance values. 13. The method of claim 7 , further comprising graphing the plurality of complex impedance values in the Fourier domain to create the printing fluid signature. 14. A printing device, comprising: a printhead; and a sensor coupled to the printhead to detect a plurality of complex impedance values of a printing fluid at the printhead; wherein the printhead comprises a number of nozzles to eject the printing fluid, and the sensor comprises two electrodes at a nozzle of the printhead, the two electrodes disposed and being spaced apart around an opening of the nozzle. 15. The printing device of claim 14 , further comprising a printing fluid complex impedance database to compare the detected complex impedance values of the printing fluid with the complex impedance values of other printing fluids. 16. The printing device of claim 14 , wherein the two electrodes are separated by a distance of 300 μm or more. 17. The printing device of claim 14 , further comprising: a processor to transform the plurality of complex impedance values into Fourier domain to create a current printing fluid signature; and a database of printing fluid signatures each based on a plurality of complex impedance values transformed into Fourier domain, the processor to compare the current signature to the signatures of the database to characterize the printing fluid provided to the printhead. 18. The printing device of claim 14 , wherein the two electrodes face each other from opposite sides of the nozzle opening.