High current event mitigation circuit

What is claimed is: 1. A protection circuit, comprising: a first resistive element configured for coupling to a protected circuit, wherein the first resistive element has a particular resistance value; a voltage regulator coupled to the first resistive element; a bypass capacitor coupled to the first resistive element and to the voltage regulator; and a second resistive element coupled to the bypass capacitor and configured for coupling between the bypass capacitor and the protected circuit, wherein the particular resistance value is selected to enable a magnitude of a bias current provided to the protected circuit to remain within a first operating current range associated with the protected circuit and to remain below a latchup holding current value associated with the protected circuit, and wherein a capacitance value of the bypass capacitor is less than or equal to 0.1 microfarads, and wherein a resistance value of the second resistive element is less than or equal to 10 ohms. 2. The protection circuit of claim 1 , further comprising the protected circuit coupled to the first resistive element and to the voltage regulator, wherein the bias current is generated via the first resistive element and the voltage regulator. 3. The protection circuit of claim 1 , wherein the voltage regulator and the first resistive element are configured to mitigate an effect of a high current event caused by a collision of a charged particle with the protected circuit. 4. The protection circuit of claim 1 , wherein the magnitude of the bias current being below the latchup holding current value enables the protected circuit to autonomously transition from a latchup state to a normal operating state after a high current event. 5. The protection circuit of claim 4 , wherein the protected circuit remains coupled to one or more power supplies during a transition of the protected circuit from the latchup state to the normal operating state. 6. The protection circuit of claim 1 , wherein the first resistive element comprises a resistor. 7. The protection circuit of claim 1 , wherein the first resistive element comprises a current source. 8. The protection circuit of claim 1 , wherein the second resistive element is configured to reduce energy provided to the protected circuit during a high current event by dissipating a portion of the energy from the protection circuit without providing the portion of the energy to the protected circuit. 9. The protection circuit of claim 1 , wherein the first resistive element is coupled between a power supply and a particular node, wherein the voltage regulator and the bypass capacitor are coupled between the particular node and ground, and wherein the second resistive element is coupled between the particular node and the protected circuit. 10. A circuit comprising: a protected circuit; and a protection circuit coupled to the protected circuit, wherein the protection circuit comprises: a first resistive element; a voltage regulator coupled to the first resistive element; a bypass capacitor coupled to the voltage regulator and to the first resistive element; and a second resistive element coupled between the bypass capacitor and the protected circuit, wherein the second resistive element is configured to reduce energy provided to the protected circuit during a high current event by dissipating a portion of the energy from the protection circuit without providing the portion of the energy to the protected circuit, wherein the first resistive element is coupled between a power supply and a particular node, wherein the voltage regulator and the bypass capacitor are coupled between the articular node and ground, and wherein the second resistive element is coupled between the particular node and the protected circuit. 11. The circuit of claim 10 , wherein the bypass capacitor is coupled to the protected circuit. 12. The circuit of claim 10 , wherein a particular resistance value of the second resistive element is selected to enable the protected circuit to transition from a latchup state to a normal operating state without decoupling the power supply from the protection circuit. 13. The circuit of claim 10 , wherein a particular resistance value of the second resistive element is selected based on a threshold energy level, a threshold temperature, a latent damage threshold latchup time period, or a combination thereof. 14. The circuit of claim 13 , wherein a capacitance value of the bypass capacitor is selected based on the threshold energy level, the threshold temperature, the latent damage threshold latchup time period, or a combination thereof, and based on a switching noise tolerance of the protected circuit. 15. The circuit of claim 10 , wherein the second resistive element and the bypass capacitor are configured to prevent energy provided to the protected circuit during the high current event from reaching a threshold energy level, and wherein the threshold energy level is associated with a potential latent failure within the protected circuit. 16. The circuit of claim 10 , wherein a capacitance value of the bypass capacitor is less than or equal to 0.1 microfarads, and wherein a resistance value of the second resistive element is less than or equal to 10 ohms. 17. A method comprising: providing a bias current to a protected circuit, wherein the bias current is provided by a protection circuit coupled to the protected circuit; and dissipating energy in the protection circuit during a high current event that causes the protected circuit to enter a latchup state, wherein the protection circuit dissipates sufficient energy to enable the protected circuit to autonomously exit the latchup state, wherein dissipating the energy in the protection circuit maintains a temperature of the protected circuit below a threshold temperature during the high current event, and wherein the protection circuit is configured to mitigate an effect of the high current event caused by a collision of a charged particle with the protected circuit. 18. The method of claim 17 , wherein the protected circuit exits from the latchup state to a normal operating state without decoupling a power supply coupled to the protection circuit. 19. The method of claim 17 , wherein dissipating the energy in the protection circuit maintains a time period the protected circuit is in the latchup state below a latent damage threshold latchup time period. 20. The method of claim 19 , wherein the protection circuit comprises a bypass capacitor and a resistive element coupled between the bypass capacitor and the protected circuit, and wherein the time period is based on a resistance of the resistive element and a capacitance of the bypass capacitor. 21. A protection circuit, comprising: a first resistive element configured for coupling to a protected circuit, wherein the first resistive element has a particular resistance value; and a voltage regulator coupled to the first resistive element, wherein the particular resistance value is selected to enable a magnitude of a bias current provided to the protected circuit to remain within a first operating current range associated with the protected circuit and to remain below a latchup holding current value associated with the protected circuit, and wherein the voltage regulator and the first resistive element are configured to mitigate an effect of a high current event caused by a collision of a charged particle with the protected circuit. 22. A circuit comprising