Power boost module

What is claimed is: 1. A power boost module configured for use with a door closer, the door closer comprising a closer body and a pinion rotatably mounted to the closer body, the power boost module comprising: a housing defining a chamber, wherein the housing is configured for mounting to at least one of the closer body or a structure to which the closer body is mounted; a clutch seated in the chamber, the clutch comprising a clutch input component and a clutch output component, wherein the clutch output component is configured for rotational coupling with the pinion such that a rotational position of the clutch output component corresponds to a rotational position of the pinion, wherein the clutch is configured to permit the clutch output component to rotate relative to the clutch input component, and wherein the clutch is configured to cause rotation of the clutch output component in response to rotation of the clutch input component; a motor seated in the chamber, the motor including a motor shaft operably connected with the clutch input component such that rotation of the motor shaft causes a corresponding rotation of the clutch input component; a position sensor operable to sense the rotational position of the clutch output component; and a controller in communication with the position sensor and the motor, wherein the controller is configured to determine the rotational position of the clutch output component based upon information received from the position sensor, and to selectively operate the motor based upon the rotational position of the clutch output component. 2. The power boost module of claim 1 , further comprising a reduction gear set engaged between the motor and the clutch input component. 3. The power boost module of claim 2 , wherein the reduction gear set comprises an input gear connected with the motor shaft and an output gear connected with the clutch input component; wherein the reduction gear set is configured to translate a first torque imparted to the input gear by the motor shaft into a second torque imparted to the clutch input component by the output gear; and wherein the second torque is higher than the first torque. 4. The power boost module of claim 2 , wherein the reduction gear set comprises a planetary gear set. 5. The power boost module of claim 4 , wherein a ring gear of the planetary gear set is coupled with the housing. 6. The power boost module of claim 1 , wherein the clutch input component comprises a post having a polygonal cross-section including a plurality of faces; wherein the clutch output component comprises a clutch chamber in which the post is received, the clutch chamber having a circular inner wall facing the plurality of faces; and wherein the clutch further comprises: a bearing cage mounted in the clutch chamber, the bearing cage defining a plurality of slots; and a plurality of roller bearings, wherein each of the plurality of roller bearings is mounted in a corresponding one of the plurality of slots between the circular inner wall and a corresponding one of the plurality of faces. 7. The power boost module of claim 1 , further comprising an onboard power supply operable to supply electrical power to the controller and the motor. 8. A door closer assembly comprising the power boost module of claim 1 , and further comprising the door closer; wherein the housing is removably secured to the closer body; and wherein the clutch output component is rotationally coupled with the pinion. 9. A method of operating a door closer assembly comprising a closer body, a pinion rotatably mounted to the closer body, a motor including a motor shaft, and a bidirectional clutch connected between the pinion and the motor shaft, the method comprising: permitting, by the bidirectional clutch, rotation of the pinion in each of a first direction and a second direction without transmitting rotation of the pinion to the motor shaft in either the first direction or the second direction; sensing, with a sensor, a rotational position of the pinion; comparing, by a controller, the rotational position of the pinion with a desired rotational position of the pinion; based upon the comparing, driving the motor to rotate the motor shaft; and by the bidirectional clutch, coupling the motor shaft with the pinion in response to rotation of the motor shaft, thereby transmitting torque from the motor shaft to the pinion and urging the pinion toward the desired rotational position of the pinion. 10. The method of claim 9 , wherein the door closer assembly is mounted to a closure assembly comprising a doorframe and a door swingingly mounted to the doorframe; and wherein the desired rotational position of the pinion corresponds to a closed position of the door. 11. The method of claim 9 , further comprising installing a power boost module to an existing door closer to form the door closer assembly; wherein the power boost module includes a housing, the bidirectional clutch, the sensor, the controller, and the motor; wherein the existing door closer comprises the closer body and the pinion; and wherein installing the power boost module comprises mounting the housing to the closer body, and rotationally coupling the pinion with a clutch output component of the bidirectional clutch. 12. The method of claim 9 , wherein the bidirectional clutch comprises a clutch input component connected with the motor shaft and a clutch output component engaged between the clutch input component and the pinion; wherein permitting rotation of the pinion in each of the first direction and the second direction without transmitting rotation of the pinion to the motor shaft in either the first direction or the second direction comprises permitting rotation of the clutch output component relative to the clutch input component in each of the first direction and the second direction without transmitting rotation of the clutch output component to the clutch input component in either the first direction or the second direction; and wherein coupling the motor shaft with the pinion in response to rotation of the motor shaft comprises coupling the clutch input component with the clutch output component in response to rotation of the clutch input component. 13. The method of claim 9 , wherein the door closer assembly further comprises a reduction gear set connected between the motor shaft and the bidirectional clutch; wherein the method further comprises increasing, by the reduction gear set, a first torque imparted on the reduction gear set by the motor shaft to a second torque imparted by the reduction gear set on the bidirectional clutch; and wherein the second torque is greater than the first torque. 14. The method of claim 9 , wherein the bidirectional clutch comprises a clutch output component and a clutch input component; wherein the clutch output component is engaged with the pinion such that a rotational position of the clutch output component corresponds to the rotational position of the pinion; wherein the clutch input component is connected between the motor shaft and the clutch output component; and wherein sensing the rotational position of the pinion comprises sensing the rotational position of the clutch output component. 15. The method of claim 9 , wherein driving the motor comprises driving the motor with electrical power supplied by an onboard power supply of the door closer assembly. 16. A door closer assembly, comprising: a closer body; a pinion rotatably mounted to the closer body, wherein the pinion has a rotational position and is rotatable in each of a