Abstract: In many aspects, the systems and methods described herein include circuitry for an intermediate bus converter for use in a datacenter. The systems and methods described herein describe an intermediate bus converter comprising power stage circuitry, comprising a non-isolated converter, configured to convert a DC source voltage to one or more DC output voltages, wherein the DC source voltage is received from a front-end AC-to-DC converter. The intermediate bus converter further comprising controller circuitry configured to receive both the DC source voltage and the DC output voltage, and generate an at least one control signal to control the operation of the power stage circuitry.

Abstract: Systems and methods are provided for cooling electronic equipment in a data center. Ambient air is vertically circulated from a workspace across a plurality of rack-mounted electronic devices. The electronic devices are located in a plurality of trays such that each tray has a major plane that is substantially parallel to a side plane of the rack. The circulated air is cooled with a heat exchanger that is connected to a vertical end of the rack via a sealed interface. Multiple racks can be arrayed in a distributed cooling arrangement, which increases reliability and scalability of the data center.

Abstract: The present technology is related generally to a switching mode power supply with virtual current sensing. The switching mode power supply comprises a power stage that includes a first power switch and a second power switch coupled in series. The switching mode power supply senses a first current flowing through the first power switch during on-time and provides a virtual current sense signal that is proportional to a second current flowing through the second power switch during on-time. The switching mode power supply further combines the real current sense signal and the virtual current sense signal to form a current sense signal, which is sent to the controller to realize desired control.

Abstract: The present technology discloses a switching mode power supply with predicted PWM control. In one embodiment, the switching mode power supply monitors the slew rate of COMP signal which represents the output voltage of the switching mode power supply. When the load steps up, the ON state of the power stage is prolonged; when the load steps down, the power stage is turned off earlier.

Abstract: Systems and methods for reliable and efficient hot swap control are disclosed herein. The system includes a feedback circuit that senses a load voltage and enables a gate driver, in response to a difference between input and output voltages falling below a predefined threshold value. Once enabled, the gate driver instantaneously, or almost instantaneously, turns on a set of paralleled metal-oxide-semiconductor field-effect transistors (MOSFETs) in a hot swap control circuit and/or enables a load. Since the MOSFETs are switched instantaneously, or almost instantaneously, they do not operate in a linear mode and thus reliable sharing of load current is achieved. In addition, on detecting an overcurrent condition, the gate driver is disabled, which in turn switches off the MOSFETs. Accordingly, both inrush current limiting and overcurrent protection can be provided.

Abstract: The present technology is related generally to a switching mode power supply with virtual current sensing. The switching mode power supply comprises a power stage that includes a first power switch and a second power switch coupled in series. The switching mode power supply senses a first current flowing through the first power switch during on-time and provides a virtual current sense signal that is proportional to a second current flowing through the second power switch during on-time. The switching mode power supply further combines the real current sense signal and the virtual current sense signal to form a current sense signal, which is sent to the controller to realize desired control.

Abstract: The present technology discloses a switching mode power supply with predicted PWM control. In one embodiment, the switching mode power supply monitors the slew rate of COMP signal which represents the output voltage of the switching mode power supply. When the load steps up, the ON state of the power stage is prolonged; when the load steps down, the power stage is turned off earlier.