Installation Instructions
LISA-U2 series - System Integration Manual
UBX-13001118 - R19 Early Production Information System description
Page 72 of 175
In this case the first character sent when the module is in idle-mode will be a wake-up character and will
not be a valid communication character (see section 1.9.2.3 for the complete description).
If power saving is enabled the application circuit with the TxD and RxD lines only is not recommended.
During command mode the DTE must send to the module a wake-up character or a dummy “AT” before
each command line (see section 1.9.2.3 for the complete description), but during data mode the wake-up
character or the dummy “AT” would affect the data communication.
Additional considerations
If a 3.0 V Application Processor (DTE) is used, the voltage scaling from any 3.0 V output of the DTE to the
apposite 1.8 V input of the module (DCE) can be implemented, as an alternative low-cost solution, by means of
an appropriate voltage divider. Consider the value of the pull-up integrated at the input of the module (DCE) for
the correct selection of the voltage divider resistance values and mind that any DTE signal connected to the
module has to be tri-stated or set low when the module is in power-down mode and during the module power-
on sequence (at least until the activation of the V_INT supply output of the module), to avoid latch-up of circuits
and allow a proper boot of the module (see the remark below).Moreover, the voltage scaling from any 1.8 V
output of the cellular module (DCE) to the apposite 3.0 V input of the Application Processor (DTE) can be
implemented by means of an appropriate low-cost non-inverting buffer with open drain output. The non-
inverting buffer should be supplied by the V_INT supply output of the cellular module. Consider the value of the
pull-up integrated at each input of the DTE (if any) and the baud rate required by the application for the
appropriate selection of the resistance value for the external pull-up biased by the application processor supply
rail.
If the module USB interface is connected to the application processor, it is highly recommended to provide
direct access to RxD, TxD, CTS and RTS lines of the module for execution of firmware upgrade over
UART using the u-blox EasyFlash tool and for debug purpose: testpoints can be added on the lines to
accommodate the access and a 0 Ω series resistor must be mounted on each line to detach the module
pin from any other connected device. Otherwise, if the USB interface is not connected to the application
processor, it is highly recommended to provide direct access to VUSB_DET, USB_D+, USB_D- lines for
execution of firmware upgrade over USB and for debug purpose. In both cases, provide as well access to
RESET_N pin, or to the PWR_ON pin, or enable the DC supply connected to the VCC pin to start the
module firmware upgrade (see Firmware Update Application Note [17]).
If the UART interface is not used, all the UART interface pins can be left unconnected, but it is highly
recommended to provide direct access to the RxD, TxD, CTS and RTS lines for execution of firmware
upgrade using the u-blox EasyFlash tool and for debug purpose.
Any external signal connected to the UART interface must be tri-stated when the module is in
power-down mode, when the external reset is forced low and during the module power-on sequence (at
least for 3 s after the start-up event), to avoid latch-up of circuits and allow a proper boot of the module.
If the external signals connected to the cellular module cannot be tri-stated, insert a multi channel digital
switch (e.g. Texas Instruments SN74CB3Q16244, TS5A3159, or TS5A63157) between the two-circuit
connections and set to high impedance during module power down mode, when external reset is forced
low and during power-on sequence.