aPPenDiX C MOunTinG PReCauTiOnS
S1C17624/604/622/602/621 TeChniCal Manual
Seiko epson Corporation
aP-C-1
Appendix C Mounting Precautions
This section describes various precautions for circuit board design and IC mounting.
Oscillator circuit
• Oscillation characteristics depend on factors such as components used (resonator, R
f
, C
G
, C
D
) and circuit
board patterns. In particular, with ceramic or crystal resonators, select the appropriate external resistor (R
f
)
and capacitors (C
G
, C
D
) only after fully evaluating components actually mounted on the circuit board.
• Oscillator clock disturbances caused by noise may cause malfunctions. To prevent such disturbances, consid-
er the following points. The latest devices, in particular, are manufactured by microscopic processes, making
them especially susceptible to noise.
Areas in which noise countermeasures are especially important include the OSC2 pin and related circuit
components and wiring. OSC1 pin handling is equally important. The noise precautions required for the
OSC1 and OSC2 pins are described below. We also recommend applying similar noise countermeasures to
the high-speed oscillator circuit, such as the OSC3 and OSC4 pins and wiring.
(1) Components such as a resonator, resistors, and capacitors connected to the OSC1 (OSC3) and OSC2 (OSC4)
pins should have the shortest connections possible.
(2) Wherever possible, avoid locating digital signal lines within 3 mm of the OSC1 (OSC3) and OSC2 (OSC4)
pins or related circuit components and wiring. Rapidly-switching signals, in particular, should be kept at a
distance from these components. Since the spacing between layers of multi-layer printed circuit boards is
a mere 0.1 mm to 0.2 mm, the above precautions also apply when positioning digital signal lines on other
layers.
Never place digital signal lines alongside such components or wiring, even if more than 3 mm distance or
located on other layers. Avoid crossing wires.
(3) Use V
SS
to shield OSC1 (OSC3) and OSC2 (OSC4) pins and related wiring
(including wiring for adjacent circuit board layers). Layers wired should
be adequately shielded as shown to the right. Fully ground adjacent lay-
ers, where possible. At minimum, shield the area at least 5 mm around the
above pins and wiring.
Even after implementing these precautions, avoid configuring digital signal
lines in parallel, as described in (2) above. Avoid crossing even on discrete
layers, except for lines carrying signals with low switching frequencies.
(4) After implementing these precautions, check the output clock waveform by running the actual application
program within the product. Use an oscilloscope to check the FOUTH or FOUT1 pin output.
You can check the quality of the OSC3 output waveform via the FOUTH output. Confirm that the frequen-
cy is as designed, is free of noise, and has minimal jitter.
You can check the quality of the OSC1 waveform via the FOUT1 output. In particular, enlarge the areas
before and after the clock rising and falling edges and take special care to confirm that the regions approxi-
mately 100 ns to either side are free of clock or spiking noise.
Failure to observe precautions (1) to (3) adequately may lead to jitter in the OSC3 output and noise in the
OSC1 output. Jitter in the OSC3 output will reduce operating frequencies, while noise in the OSC1 output
will destabilize timers operated by the OSC1 clock as well as CPU Core operations when the system clock
switches to OSC1.
Reset circuit
• The reset signal input to the #RESET pin when power is turned on will vary, depending on various factors,
such as power supply start-up time, components used, and circuit board patterns. Constants such as capaci-
tance and resistance should be determined through testing with real-world products.
• Components such as capacitors and resistors connected to the #RESET pin should have the shortest connec-
tions possible to prevent noise-induced resets.
OSC4
OSC3
V
SS
Sample V
SS
pattern (OSC3)