TOBY-L2 and MPCI-L2 series - System Integration Manual
UBX-13004618 - R07
Advance Information
Design-in
Page 115 of 158
2.6.4
Secure Digital Input Output interface (SDIO)
The SDIO Secure Digital Input Output interface is not available on MPCI-L2 series modules.
2.6.4.1
Guidelines for SDIO circuit design
The functionality of the SDIO Secure Digital Input Output interface pins is not supported by TOBY-L2 “00”
and “01” product versions: the pins should not be driven by any external device.
TOBY-L2 series modules include a 4-bit Secure Digital Input Output interface (
SDIO_D0
,
SDIO_D1
,
SDIO_D2
,
SDIO_D3
,
SDIO_CLK
,
SDIO_CMD
) designed to communicate with an external u-blox short range Wi-Fi module.
Combining a u-blox cellular module with a u-blox short range communication module gives designers full access
to the Wi-Fi module directly via the cellular module, so that a second interface connected to the Wi-Fi module is
not necessary. AT commands via the AT interfaces of the cellular module (UART, USB) allows full control of the
Wi-Fi module from any host processor, because Wi-Fi control messages are relayed to the Wi-Fi module via the
dedicated SDIO interface (for more details, see the Wi-Fi AT commands in the
u-blox AT Commands Manual
and see the
Wi-Fi / Cellular Integration Application Note
Figure 65 and Table 40 show an application circuit for connecting TOBY-L2 series cellular modules “50” product
version to u-blox ELLA-W1 series short range Wi-Fi 802.11 b/g/n modules:
The SDIO pins of the cellular module are connected to the related SDIO pins of the u-blox ELLA-W1 series
short range Wi-Fi module, with appropriate low value series damping resistors to avoid reflections and other
losses in signal integrity, which may create ringing and loss of a square wave shape.
The most appropriate value for the series damping resistors on the SDIO lines depends on the specific line
lengths and layout implemented. In general, the SDIO series resistors are not strictly required, but it is
recommended to slow the SDIO signal, for example with 22
or 33
resistors, and avoid any possible
ringing problem without violating the rise / fall time requirements.
The
V_INT
supply output pin of the cellular module is connected to the shutdown input pin (
SHDNn
) of the
two LDO regulators providing the 3.3 V and 1.8 V supply rails for the u-blox ELLA-W1 series Wi-Fi module,
with appropriate pull-down resistors to avoid an improper switch on of the Wi-Fi module before the switch-
on of the
V_INT
supply source of the cellular module SDIO interface pins.
The
GPIO1
pin of the cellular module is connected to the active low full power down input pin (
PDn
) of the
u-blox ELLA-W1 series Wi-Fi module, implementing the Wi-Fi enable function.
The configuration pin (
CFG
) of the u-blox ELLA-W1 series Wi-Fi module is connected to ground by means of
a proper pull-down resistor for operation without sleep clock
The sleep clock input pin (
SLEEP_CLK
) of the u-blox ELLA-W1 series Wi-Fi module is left not connected,
because an external clock source is not required for full power mode and automotive use.
The WLAN LED open drain output pin (
LED_0
) of the u-blox ELLA-W1 series Wi-Fi module is connected to
an LED with appropriate current limiting resistor, indicating Wi-Fi activity as additional optional feature.
The WLAN antenna RF input/output (
ANT1
) of the u-blox ELLA-W1 series Wi-Fi module is connected to a
Wi-Fi antenna with an appropriate series Wi-Fi band-pass filter specifically designed for the coexistence
between the Wi-Fi RF signals (2402...2482 MHz) and the LTE band 7 RF signals (2500...2690 MHz), as for
example the Wi-Fi BAW band-pass filter TDK EPCOS B9604, or the TriQuint 885071, or the TriQuint 885032
or the Avago ACPF-7424, or the Taiyo Yuden F6HF2G441AF46.
All
GND
pins of the cellular module and the u-blox ELLA-W1 series Wi-Fi module are connected to ground.
All the other pins of the u-blox ELLA-W1 series Wi-Fi module are intended to be not connected.
