Micrel
MICRF405
April 2006
31
M9999-041906
(408) 955-1690
The two first blocks are generating a clock for the
modulator. This clock is, together with the user data,
used to control a charge pump. The charge pump
current is controlled by a DAC. Each time the input
data changes state, a charge is then injected into
the capacitor to generate a modulation signal. The
charge magnitude is controlled by the charging
current and by charging time (inversely proportional
with modulator clock). To be able to achieve small
deviations, it is possible to attenuate the modulation
signal. Finally, the signal is filtered to narrow
transmitter output spectrum.
The procedure is first to determine the settings
concerning the data bit rate, then, these values will
be used in the calculation of the frequency deviation.
Finally, the user must see if the desired values
cause the modulator to saturate.
Deviation Setting
Deviation controlled by user parameters FSKClk_K,
MOD_I,   and   MOD_A,   together   with   physical
parameters fXTAL and KVCO. All user parameters
can be set in software, and fXTAL (crystal oscillator
frequency) is set when designing in the radio chip.
KVCO (VCO gain) is a parameter of the radio chip,
and is not controllable by the user.
The crystal oscillator frequency, fXTAL, is divided by
FSKClk_K to generate the modulator clock. Since
this modulator clock is controlling the rise and fall
times for the modulator, the frequency deviation is
inversely proportional to this clock. The relationship
is shown in equation (3):
XTAL
DEV
f
FSKClk_K
f
(3)
It is assumed that FSKClk_K will be constant for
most applications to keep bit-rate and shaping
constant, although this is not a requirement.
The primary two controls of frequency deviation are
MOD_I and MOD_A. Of these two, MOD_I is the
parameter that controls the signal generation, while
MOD_A controls attenuation of this signal. The
reason for using an attenuator is to be able to
generate   small   deviations   at   high   values   of
FSKClk_K. The relationship is shown in equation
(4).
A
MOD
DEV
I
MOD
f
_
2
_
(4)
Finally, the VCO gain is given by equation (5).
(
)
(
)
FreqBand
FreqBand
f
Const
Const
K
C
VCO
?/DIV>
?/DIV>
+
=
3
3
2
1
(5)
where:
Const1
9
10
6324
.
30
?/DIV>
Const2     7
.
54   
fC: Carrier frequency of the radio.
FreqBand: Frequency band.
    0: 315MHz,
    1: 433MHz and
    2: 900MHz.
In equation (5), it is evident that the VCO gain is
dependent of carrier frequency. MOD_I is probably
the best parameter to alter if counteracting this effect
if necessary.
Combining equations (3), (4), and (5) gives us an
expression for the frequency deviation:
(
)
(
)
FreqBand
FreqBand
f
Const
Const
I
MOD
f
f
C
A
MOD
XTAL
DEV
?/DIV>
?/DIV>
+
?/DIV>
?/DIV>
=
3
3
2
_
FSKClk_K
2
1
_
(6)
Observe   that   equation   (6)   gives   single-sided-
deviation. Peak-to-peak deviation is twice this value.
Shaping
The modulation waveform will be shaped due to the
charging   and   discharging   of   a   capacitor.   The
waveform looks like a Gaussian filtered signal with a
Bandwidth臥eriod-product, BT, given by:
FSKn
BT   2
=
(7)
where:
BT: Shaping factor.
It is evident from this that a low FSKn gives a low
shaping factor, and is thus preferred if it is possible
to choose FSKn freely.
In addition to this, it is possible to smooth the
modulator output in a programmable low-pass filter.
This filter is controlled by the parameter MOD_F.
The parameter should be set according to equation
(8).
BR
F
MOD
3
10
150
_
?/DIV>
d
(8)
Modulator Saturation
The modulator output voltage is generated by a
capacitor that is being charged. This means that
there is a risk of saturating the modulator if the
charge received by the capacitor is too large. Use
equation (9) to determine the maximum value of
MOD_I that can be used.
1
10
28
_
6
+
?/DIV>
?/DIV>
?/DIV>
?/DIV>
?/DIV>
?/DIV>
?/DIV>
?/DIV>
?/DIV>
?/DIV>
d
FSKClk_K
f
I
MOD
XTAL
(9)
If it turns out that the MOD_I-range is too small for
your   requirements,   try   increasing   FSKn   and
decreasing FSKClk_K accordingly.
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