General
Review and verify the following for
the custom schematic design:
- Above sections, including
relevant application notes and FAQ links.
- Pin attributes, signal
description, and electrical specifications.
- Electrical characteristics,
timing parameters and any additional available information.
- Include a series resistor
(0Ω) on MMC1_CLK placed as close to processor clock output pin as possible
to dampen reflections. MMC1_CLK is looped back internally on read
transactions, and the resistor can be needed to eliminates possible signal
reflections, which can cause false clock transitions. Use 0Ω initially and
adjust as required to match the PCB trace impedance.
- The MMC1 CLK, CMD, and DAT0-3
signal functions are implemented with SDIO buffers on pins powered from
VDDSHV5 (power source that changes the operating voltage from 3.3V to 1.8V
as the transfer speed increases).
- The MMC1 SDCD and SDWP signal
functions are implemented with LVCMOS buffers on pins powered from VDDSHV0,
which operate at fixed 1.8V or 3.3V.
- The SDIO buffers are designed
to support dynamic voltage change. Dynamic voltage scaling is necessary
since UHS-I SD cards begins operating with 3.3V signaling and changes to
1.8V signaling when the SD card transitions to one of the higher speed data
transfer modes.Processor IO buffers are off during reset. An external
pullup is required for any of the processor or attached device IOs that can
float. Pullups are needed on all data and command signals. Verify internal
pullups are not configured when (improves noise immunity) external pullups
are used.
- To meet the SD card
specification, a 47kΩ pullup is recommended when internal pulls are
unexpectedly enabled. The 47kΩ pullup verifies the resulting pull resistance
is within the specified range.
- When UHS-I speed support is
required, implementing an LDO supply that switches between 3.3V and 1.8V is
required. Switching IO supply can be an external discrete implementation or
internal to the PMIC. Connect the switchable voltage output to the IO supply
group, referencing the SD interface signals (VDDSHV5).
- When UHS-I speed support is
required, while the IO voltage for SD card interface is either 1.8V or 3.3V,
the SD card VDD supply is connected to a fixed 3.3V source.
- When UHS-I speed support is
required, the 3.3V SD card power is required to be switched through a load
switch to allow resetting of the SD card IO supply to 3.3V. Provision to
enable the SD card load switch during reset is required.
- Provide provision to reset
the load switch using the SD card load switch EN signal during cold reset,
warm reset and normal operation using processor IO is required to be
provided. An option is a 3-input ANDing logic.
- During boot, the ROM code
checks the status of the card detect pin (SDCD, pin P23). The signal is
expected as low to indicate card is detected.
Schematic Review
Follow the below list for the custom
schematic design:
- Required bulk and decoupling
capacitors are provided. Compare with the SK schematics.
- Pull values used for the
data, command and clock signals. Compare with the relevant SK.
- Series resistor value and
placement on the clock output signal near to the processor.
- When UHS-I speed support is
required, verify the IO supply rail switching and the SD card power
switching circuits are added.
- Supply rail connected to the
SD card power supply (use SYS voltage).
- Implementation of reset logic
for resetting the SD card power control load switch. Provision for slew rate
control of the SD card supply is provided.
- Supply rails connected follow
the ROC.
- Required external ESD
protection are provided for the SD interface signals.
Additional
- The logic state of the MMC1_SDCD
and MMC1_SDWP inputs to the host must not change when a UHS-I SD card changes
the IO operating voltage. Maintaining a valid logic state is not possible if the
signals propagate through an input buffer of a dual-voltage SDIO cell that
changes voltage. The signal functions are assigned to IOs that do not change
voltage. Signals only connect to switches in the SD card connector, so there is
no reason for the signals to change voltage when the SD card signals change
operating voltage. The MMC1_SDCD and MMC1_SDWP signals are required to connect
to the SD card connector switches and pull high with external pull resistors
connected to the VDDSHV0. The other MMC1 SD card signals with pullups are
required to have pulls powered by the VDDSHV5 source that dynamically changes
voltage
- The MMC2_SDCD and MMC2_SDWP pins are referenced to the same IO supply group the
other MMC2 pins. However, it s not recommended to use the control for the
MMC2_SDCD and MMC2_SDWP signal functions if you are trying to connect an UHS-I
SD card to MMC2. For SD card use case, the signal functions needs to implemented
using one of the other pin multiplexing options that uses an IO cell powered
from a fixed voltage source. The MMC2 assignments are different because we only
expected MMC2 to be used with on-board fixed voltage SDIO devices similar to
Wi-Fi or Bluetooth transceivers
- SD card power switch, along with the power switch supply EN pin reset logic, and
the host IO power supply circuit is required to support UHS-I SD cards which
begins communications using 3.3V signal levels and later change to 1.8V signal
levels when changing to one of the faster data transfer speeds.
Cycling power
to the SD card is the only way to put it back into 3.3V mode since SD cards
do not have a reset pin. The host IO power supply must power off/on and
change voltage at the same time as the SD card. The circuits and the
software driver operating the signals sourcing the circuits verifies that
both devices are off, or on and operating at the same IO voltage at the same
time
- To optimize the ANDing logic, use a 2 input AND gate with RESETSTATz and the
processor IO as inputs
- Add a series resistor 100Ω to the SDCD pin because processor IO connects
directly to the ground when the SD card is inserted