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NCP5220MNR2 Datasheet(PDF) 10 Page - ON Semiconductor |
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NCP5220MNR2 Datasheet(HTML) 10 Page - ON Semiconductor |
10 / 18 page NCP5220 http://onsemi.com 10 DETAILED OPERATION DESCRIPTIONS General The NCP5220 3−in−1 PWM Dual Buck Linear DDR Power Controller contains two high efficiency PWM controllers and an integrated two−quadrant linear regulator. The VDDQ supply is produced by a PWM switching controller with two external N−Ch FETs. The VTT termination voltage is an integrated linear regulator with sourcing and sinking current capability which tracks at ½ VDDQ. The MCH core voltage is created by the secondary switching controller. The inclusion of soft−start, supply undervoltage monitors and thermal shutdown, makes this device a total power solution for the MCH and DDR memory system. This device is packaged in a DFN−20. ACPI Control Logic The ACPI control logic is powered by the 5VDUAL supply. It accepts external control at the SLP_S3 input and internal supply voltage monitoring signals from two UVLOs to decode the operating mode in accordance with the state transition diagram in Figure 18. These UVLOs monitor the external supplies, 5VDUAL and 12VATX, through 5VDUAL and BOOT pins respectively. Two control signals, _5VDUALGD and _BOOTGD, are asserted when the supply voltages are good. When the device is powered up initially, it is in the S5 shutdown mode to minimize the power consumption. When all three supply voltages are good with SLP_S3 and SLP_S5 remaining HIGH, the device enters the S0 normal operating mode. The transition of SLP_S3 from HIGH to LOW while in the S0 mode, triggers the device into the S3 sleep mode. In S3 mode the 12VATX supply collapses. On transition of SLP_S3 from LOW to HIGH, the device returns to S0 mode. The IC can re−enter S5 mode by setting SLP_S5 LOW. A timing diagram is shown in Figure 17. Table 1 summarizes the operating states of all the regulators, as well as the conditions of the output pins. Internal Bandgap Voltage Reference An internal bandgap reference is generated whenever 5VDUAL exceeds 2.7 V. Once this bandgap reference is in regulation, an internal signal _VREFGD will be asserted. S5 to S0 Mode Power−Up Sequence The ACPI control logic is enabled by the assertion of _VREFGD. Once the ACPI control is activated, the power− up sequence starts by waking up the 5VDUAL voltage monitor block. If the 5VDUAL supply is within the preset levels, the BOOT undervoltage monitor block is then enabled. After 12VATX is ready and the BOOT UVLO is asserted LOW, the ACPI control triggers this device from S5 shutdown mode into S0 normal operating mode by activating the soft−start of DDQ switching regulator, providing SLP_S3 and SLP_S5 remain HIGH. Once the DDQ regulator is in regulation and the soft−start interval is completed, the _InRegDDQ signal is asserted HIGH to enable the VTT regulator as well as the V1P5 switching regulator. DDQ Switching Regulator In S0 mode the DDQ regulator is a switching synchronous rectification buck controller driving two external power N−Ch FETs to supply up to 20 A. It employs voltage mode fixed frequency PWM control with external compensation switching at 250kHz ± 13.2%. As shown in Figure 2, the VDDQ output voltage is divided down and fed back to the inverting input of an internal amplifier through the FBDDQ pin to close the loop at VDDQ = VFBQ × (1 + R1/R2). This amplifier compares the feedback voltage with an internal reference voltage of 1.190 V to generate an error signal for the PWM comparator. This error signal is compared with a fixed frequency RAMP waveform derived from the internal oscillator to generate a pulse−width−modulated signal. This PWM signal drives the external N−Ch FETs via the TG_DDQ and BG_DDQ pins. External inductor L and capacitor COUT1 filter the output waveform. When the IC leaves the S5 state, the VDDQ output voltage ramps up at a soft−start rate controlled by the capacitor at the SS pin. When the regulation of VDDQ is detected in S0 mode, _INREGDDQ goes HIGH to notify the control block. In S3 standby mode, the switching frequency is doubled to reduce the conduction loss in the external N−Ch FETs. Table 1. Mode, Operation and Output Pin Conditions OPERATING CONDITIONS OUTPUT PIN CONDITIONS MODE DDQ VTT MCH TG_DDQ BG_DDQ TP_1P5 BG_1P5 S0 Normal Normal Normal Normal Normal Normal Normal S3 Standby H−Z OFF Standby Standby Low Low S5 OFF H−Z OFF Low Low Low Low |
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