Apparatus and methods for digital step attenuators with small output glitch

What is claimed is: 1. A digital step attenuator comprising: an input terminal; an output terminal; an attenuation control circuit configured to control an amount of attenuation provided by the digital step attenuator between the input terminal and the output terminal, the attenuation control circuit configured to generate a switch control signal; and an attenuation stage including a switching circuit configured to receive the switch control signal at a switch control input, the switching circuit including a field effect transistor switch, a gate resistor electrically connected between the switch control input and a gate of the field effect transistor switch, and a pulse generation circuit configured to generate one or more pulse signals in response to a transition of the switch control signal, the one or more pulse signals operable to temporarily decrease an amount of resistance between the switch control input and the gate of the field effect transistor switch. 2. The digital step attenuator of claim 1 wherein the switching circuit includes a gate resistor bypass switch controlled by the one or more pulse signals, the gate resistor bypass switch electrically connected in parallel with the gate resistor. 3. The digital step attenuator of claim 2 wherein the gate resistor bypass switch is turned on by the one or more pulse signals in response to a rising edge of the switch control signal. 4. The digital step attenuator of claim 2 wherein the gate resistor bypass switch includes a plurality of p-type field effect transistors arranged in a cascade. 5. The digital step attenuator of claim 1 wherein the switching circuit includes a gate resistor bypass switch controlled by the one or more pulse signals, the gate resistor bypass switch electrically connected between the gate of the field effect transistor switch and a first voltage. 6. The digital step attenuator of claim 5 wherein the gate resistor bypass switch is turned on by the one or more pulse signals in response to a falling edge of the switch control signal. 7. The digital step attenuator of claim 5 wherein the gate resistor bypass switch includes a plurality of n-type field effect transistors arranged in a cascade. 8. The digital step attenuator of claim 1 wherein the switching circuit is electrically connected in a bypass path of the attenuation stage. 9. The digital step attenuator of claim 8 wherein the attenuation stage further includes a glitch reduction switch electrically connected in shunt to the bypass path and controlled by the one or more pulse signals. 10. The digital step attenuator of claim 9 wherein the glitch reduction switch is turned on by the one or more pulse signals in response to a falling edge of the switch control signal. 11. The digital step attenuator of claim 8 further comprising a phase compensation inductor electrically connected in the bypass path. 12. The digital step attenuator of claim 1 wherein the attenuation stage further includes an attenuation circuit electrically connected in an attenuation path of the attenuation stage, the switching circuit electrically connected in shunt to the attenuation path. 13. A front-end module comprising: a low noise amplifier configured to generate a radio frequency signal; and a digital step attenuator including an attenuation control circuit configured to control an amount of attenuation provided to the radio frequency signal and to generate a switch control signal, the digital step attenuator further including an attenuation stage including a switching circuit configured to receive the switch control signal at a switch control input, the switching circuit including a field effect transistor switch, a gate resistor electrically connected between the switch control input and a gate of the field effect transistor switch, and a pulse generation circuit configured to generate one or more pulse signals in response to a transition of the switch control signal, the one or more pulse signals operable to temporarily decrease an amount of resistance between the switch control input and the gate of the field effect transistor switch. 14. The front-end module of claim 13 further comprising a laminated substrate and a die attached to the laminated substrate, the die including the low noise amplifier and the digital step attenuator. 15. The front-end module of claim 13 wherein the switching circuit includes a gate resistor bypass switch controlled by the one or more pulse signals, the gate resistor bypass switch electrically connected in parallel with the gate resistor. 16. The front-end module of claim 13 wherein the switching circuit includes a gate resistor bypass switch controlled by the one or more pulse signals, the gate resistor bypass switch electrically connected between the gate of the field effect transistor switch and a first voltage. 17. The front-end module of claim 13 wherein the switching circuit is electrically connected in a bypass path of the attenuation stage, the attenuation stage further including a glitch reduction switch electrically connected in shunt to the bypass path and controlled by the one or more pulse signals. 18. A mobile device comprising: a phone board; and a front-end module attached to the phone board, the front-end module including a low noise amplifier configured to generate a radio frequency signal, and a digital step attenuator including an attenuation control circuit configured to control an amount of attenuation provided to the radio frequency signal and to generate a switch control signal, the digital step attenuator further including an attenuation stage including a switching circuit configured to receive the switch control signal at a switch control input, the switching circuit including a field effect transistor switch, a gate resistor electrically connected between the switch control input and a gate of the field effect transistor switch, and a pulse generation circuit configured to generate one or more pulse signals in response to a transition of the switch control signal, the one or more pulse signals operable to temporarily decrease an amount of resistance between the switch control input and the gate of the field effect transistor switch. 19. The mobile device of claim 18 wherein the switching circuit includes a gate resistor bypass switch controlled by the one or more pulse signals, the gate resistor bypass switch electrically connected in parallel with the gate resistor. 20. The front-end module of claim 18 wherein the switching circuit includes a gate resistor bypass switch controlled by the one or more pulse signals, the gate resistor bypass switch electrically connected between the gate of the field effect transistor switch and a first voltage.