SLVA340A Datasheet, PDF(2/9 Page) Texas Instruments – High-Integration, High-Efficiency Power Solution Using DC/DC Converters With DVFS

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SLVA340A Datasheet, PDF (2/9 Pages) Texas Instruments – High-Integration, High-Efficiency Power Solution Using DC/DC Converters With DVFS

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Power Requirements

www.ti.com

Another potential problem with improper supply sequencing is bus contention. Bus contention is a

condition when the processor and another device both attempt to control a bi-directional bus during power

up. Bus contention may also affect I/O reliability. Power supply designers should check the requirements

regarding bus contention for individual devices.

The power-on sequencing for the OMAP-L138, TMS320C6742, TMS320C6746, and TMS320C6748 are

shown in the Power Requirements table below. There is no specific required voltage ramp rate for any of

the supplies as long as the 3.3V rail never exceeds the 1.8V rail by more than 2V.

Also, in order to reduce the power consumption of the processor core, the Dynamic Voltage and

Frequency Scaling (DVFS) is used in the reference design. DVFS is a power management technique used

while the system-on-chip (SoC) is actively processing. This technique matches the operating frequency of

the hardware to the performance requirement of the active application scenario. Whenever clock

frequencies are lowered, operating voltages are also lowered as well to achieve power savings. In the

reference design, the TPS65023 is used that can scale its output voltage. It supports all five DVFS voltage

values (0.95V, 1V, 1.2V, 1.27V, and 1.35V) defined for VDD_MPU.

2 Power Requirements

The power requirements are as specify in the table.

PIN NAME

VOLTAGE (1) (2)

(V)

Imax

(mA)

TOLERANCE

SEQUENCING

ORDER

TIMING

DELAY

I/O

RTC_CVDD

1.2

â25%, +10%

1 (3)

Core CVDD(4)

1.0 / 1.1 / 1.2

600

â9.75%, +10%

I/O

RVDD, PLL0_VDDA,

PLL1_VDDA, SATA_VDD,

USB_CVDD, USB0_VDDA12

1.2

200

â5%, +10%

I/O

USB0_VDDA18, USB1_VDDA18,

1.8

180

Â±5%

DDR_DVDD18, SATA_VDDR,

DVDD18

I/O

USB0_VDDA33, USB1_VDDA33

3.3

Â±5%

I/O

DVDD3318_A, DVDD3318_B,

DVDD3318_C

1.8 / 3.3

50 / 90(5)

Â±5%

4/5

(1) If 1.8-V LVCMOS is used, power rails up with the 1.8-V rails. If 3.3-V LVCMOS is used, power it up with the ANALOG33 rails

(VDDA33_USB0/1)

(2) There is no specific required voltage ramp rate for any of the supplies LVCMOS33 (USB0_VDDA33, USB1_VDDA33) never

exceeds STATIC18 (USB0_VDDA18, USB1_VDDA18, DDR_DVDD18, SATA_VDDR, DVDD18) by more than 2 V.

(3) If RTC is not used/maintained on a separate supply, it can be included in the STATIC12 (fixed 1.2 V) group.

(4) If using CVDD at fixed 1.2 V, all 1.2-V rails may be combined.

(5) If DVDD3318_A, B, and C are powered independently, maximum power for each rail will be 1/3 the above maximum power.

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With

DVFS

SLVA340A â June 2009 â Revised May 2010

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