Rotating saw with balanced dynamic braking

The invention claimed is: 1. A method of operating an automatic braking system for a pivoting power tool, comprising: supporting a cutting assembly with a cutting arm; sensing an unsafe condition using a safety circuit; controlling with the safety circuit a primary braking system to oppose rotation of a blade supported by the cutting assembly in response to sensing the unsafe condition; and controlling with the safety circuit a secondary braking system to oppose rotation of the cutting arm in response to sensing the unsafe condition; disengaging with the safety circuit a primary clutch through which the primary braking assembly is operably connected to a motor in response to sensing the unsafe condition; and disengaging with the safety circuit a secondary clutch through which the secondary braking assembly is operably connected to the motor in response to sensing the unsafe condition. 2. The method of claim 1 further comprising: rotating the blade with the motor through a pulley operably connected to the primary clutch prior to sensing the unsafe condition. 3. The method of claim 1 , further comprising: generating a first moment of inertia by controlling with the safety circuit the primary braking system to oppose rotation of the blade; and generating a second moment of inertia by controlling with the safety circuit the secondary braking system to oppose rotation of the cutting arm, wherein the second moment of inertia has a magnitude substantially the same as the magnitude of the first moment of inertia. 4. The method of claim 1 , wherein controlling with the safety circuit the primary braking system to oppose rotation of the blade occurs substantially simultaneously with controlling with the safety circuit the secondary braking system to oppose rotation of the cutting arm. 5. The method of claim 1 further comprising: rotating the primary clutch with the motor through a first gear prior to sensing the unsafe condition; and rotating the secondary clutch with the motor through a second gear and a reversing gear prior to sensing the unsafe condition. 6. The method of claim 5 , wherein: rotating the primary clutch comprises rotating the primary braking system at a first speed with the primary clutch; rotating the secondary clutch comprises rotating the secondary braking system at a second speed with the secondary clutch; and the second speed is greater the first speed. 7. An automatic braking system for a pivoting power tool, comprising: a cutting assembly; a cutting arm supporting the cutting assembly; a hinge supporting the cutting arm through a pivot; a primary braking system operably connected to the cutting assembly; a secondary braking system operably connected to the hinge; and a safety circuit configured to sense an unsafe condition and, in response to sensing the unsafe condition, (i) control the primary braking system to oppose rotation of a blade supported by the cutting assembly, and (ii) control the secondary braking system to oppose rotation of the cutting arm; wherein: the primary braking assembly is operably connected to a motor through a primary clutch; the secondary braking assembly is operably connected to the motor through a secondary clutch; and the safety circuit is configured to disengage the primary clutch and the secondary clutch in response to sensing the unsafe condition. 8. The automatic braking system of claim 1 , wherein: the primary braking assembly is operably positioned between the primary clutch and a pulley, the pulley operably connected to the blade. 9. The automatic braking system of claim 1 , wherein: the primary clutch is operably connected to the motor through a first gear; and the secondary clutch is operably connected to the motor through a second gear and a reversing gear. 10. The automatic braking system of claim 1 , wherein the secondary braking assembly is sized to produce a moment of inertia of substantially the same magnitude as a moment of inertia generated by the primary braking assembly. 11. The automatic braking system of claim 10 , wherein the secondary braking system is smaller in size than the primary braking assembly.