Scalable Low Dropout Regulator

Organization Name

APPLE INC.

Inventor(s)

Michael P. Wigley of Swindon (GB)

Tiago Filipe Galhoz Patrao of Swindon (GB)

Mircea-Andrei Lazar of Newbury (GB)

Nathan F. Hanagami of San Francisco CA (US)

Jay B. Fletcher of Saratoga CA (US)

Enrico Zanetti of Cascina (IT)

Scalable Low Dropout Regulator - A simplified explanation of the abstract

This abstract first appeared for US patent application 17806908 titled 'Scalable Low Dropout Regulator

Simplified Explanation

The patent application describes a regulator circuit for a computer system that adjusts the conductance values between an input power supply node and a regulated power supply node. This is done by using a control circuit and multiple pass circuits. The number of pass circuits can be adjusted based on a threshold load current or a threshold conductance.

• The regulator circuit includes a control circuit and multiple pass circuits.
• The pass circuits adjust the conductance values between the input power supply node and the regulated power supply node.
• The number of pass circuits can be adjusted based on a threshold load current or a threshold conductance.
• The control circuit uses sense currents, a reference voltage, and the voltage level of the regulated power supply node to adjust the conductance values.

Potential applications of this technology:

• Computer systems
• Electronic devices
• Power supply systems

Problems solved by this technology:

• Efficiently regulating power supply in computer systems and electronic devices
• Adjusting conductance values based on load current or conductance thresholds

Benefits of this technology:

• Improved power regulation in computer systems and electronic devices
• Flexibility to adjust the number of pass circuits based on specific requirements
• Efficient use of power supply resources

Original Abstract Submitted

A regulator circuit included in a computer system may include a control circuit and multiple pass circuits that source respective supply currents to a regulated power supply node by adjusting respective conductance values between an input power supply node and the regulated power supply node. The number of pass circuits can be adjusted on a design-by-design basis based on a threshold load current for the regulator circuit or on a threshold conductance between the input power supply node and the regulated power supply node. The control circuit adjusts the respective conductance values using a combination of respective sense currents generated by the multiple pass circuits along with a reference voltage and a voltage level of the regulated power supply node.