CC3200MOD_15 Datasheet, PDF(45/66 Page) Texas Instruments – CC3200MOD SimpleLink™ Wi-Fi® and Internet-of-Things Module Solution, a Single-Chip Wireless MCU

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CC3200MOD_15 Datasheet, PDF (45/66 Pages) Texas Instruments – CC3200MOD SimpleLink™ Wi-Fi® and Internet-of-Things Module Solution, a Single-Chip Wireless MCU

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CC3200MOD

SWRS166 â DECEMBER 2014

5.6 Power-Management Subsystem

The CC3200 power-management subsystem contains DC-DC converters to accommodate the differing

voltage or current requirements of the system. The module can operate from an input voltage ranging from

2.3 V to 3.6 V and can be directly connected to 2xAA Alkaline batteries.

The CC3200MOD is a fully integrated module based WLAN radio solution used on an embedded system

with a wide-voltage supply range. The internal power management, including DC-DC converters and

LDOs, generates all of the voltages required for the module to operate from a wide variety of input

sources. For maximum flexibility, the module can operate in the modes described in the following sections.

5.6.1 VBAT Wide-Voltage Connection

In the wide-voltage battery connection, the module is powered directly by the battery or preregulated 3.3-V

supply. All other voltages required to operate the device are generated internally by the DC-DC

converters. This scheme is the most common mode for the device as it supports wide-voltage operation

from 2.3 to 3.6 V.

5.7 Low-Power Operating Mode

From a power-management perspective, the CC3200 device comprises the following two independent

subsystems:

â¢ Cortex-M4 application processor subsystem

â¢ Networking subsystem

Each subsystem operates in one of several power states.

The Cortex-M4 application processor runs the user application loaded from an external serial flash. The

networking subsystem runs preprogrammed TCP/IP and Wi-Fi data link layer functions.

The user program controls the power state of the application processor subsystem and can be in one of

the five modes described in Table 5-2.

NOTE

Table 5-2 lists the modes by power consumption, with highest power modes listed first.

Table 5-2. User Program Modes

APPLICATION PROCESSOR

(MCU) MODE

MCU active mode

MCU sleep mode

MCU LPDS mode

MCU hibernate mode

DESCRIPTION

MCU executing code at 80-MHz state rate

The MCU clocks are gated off in sleep mode and the entire state of the device is retained. Sleep mode

offers instant wakeup. The MCU can be configured to wake up by an internal fast timer or by activity

from any GPIO line or peripheral.

State information is lost and only certain MCU-specific register configurations are retained. The MCU

can wake up from external events or by using an internal timer. (The wake-up time is less than 3 ms.)

Certain parts of memory can be retained while the MCU is in LPDS mode. The amount of memory

retained is configurable. Users can choose to preserve code and the MCU-specific setting. The MCU

can be configured to wake up using the RTC timer or by an external event on specific GPIOs defined in

Table 3-2 as the wake-up source.

The lowest power mode in which all digital logic is power-gated. Only a small section of the logic directly

supports wakeup from an external event or from an RTC timer expiry. Wake-up time is longer than

LPDS mode at about 15 ms plus the time to load the application from serial flash, which varies

according to code size. In this mode, the MCU can be configured to wake up using the RTC timer or

external event on a GPIO (GPIO0âGPIO6).

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