Si4421 Universal ISM Band
FSK Transceiver
Si4421
PIN ASSIGNMENT
DESCRIPTION
Silicon Labs’ Si4421 is a single chip, low power, multi-channel FSK
transceiver designed for use in applications requiring FCC or ETSI
conformance for unlicensed use in the 433, 868 and 915 MHz bands.
The Si4421 transceiver is a part of Silicon Labs’ EZRadioTM product
line, which produces a flexible, low cost, and highly integrated solution
that does not require production alignments. The chip is a complete
analog RF and baseband transceiver including a multi-band PLL
synthesizer with PA, LNA, I/Q down converter mixers, baseband filters
and amplifiers, and an I/Q demodulator. All required RF functions are
integrated. Only an external crystal and bypass filtering are needed for
operation.
The Si4421 features a completely integrated PLL for easy RF design,
and its rapid settling time allows for fast frequency-hopping, bypassing
multipath fading and interference to achieve robust wireless links. The
PLL’s high resolution allows the usage of multiple channels in any of
the bands. The receiver baseband bandwidth (BW) is programmable to
accommodate various deviation, data rate and crystal tolerance
requirements. The transceiver employs the Zero-IF approach with I/Q
demodulation. Consequently, no external components (except crystal
and decoupling) are needed in most applications.
The Si4421 dramatically reduces the load on the microcontroller with
the integrated digital data processing features: data filtering, clock
recovery, data pattern recognition, integrated FIFO and TX data
register. The automatic frequency control (AFC) feature allows the use
of a low accuracy (low cost) crystal. To minimize the system cost, the
Si4421 can provide a clock signal for the microcontroller, avoiding the
need for two crystals.
For low power applications, the Si4421 supports low duty cycle
operation based on the internal wake-up timer.
FUNCTIONAL BLOCK DIAGRAM
MIX
I
AMP
OC
7
clk
RF1 13
RF2 12
MIX
Q
AMP
Data Filt
CLK Rec
I/Q
DEMOD
Self cal.
LNA
data
OC
PA
FIFO
RSSI
PLL & I/Q VCO
with cal.
RF Parts
COMP
DQD
AFC
BB Amp/Filt./Limiter
CLK div
Xosc
WTM
with cal.
Data processing units
6
DCLK /
CFIL /
FFIT /
FSK /
DATA /
nFFS
This document refers to Si4421-IC rev A1.
See www.silabs.com/integration for any applicable errata.
See back page for ordering information.
FEATURES
Fully integrated (low BOM, easy design-in)
No alignment required in production
Fast-settling, programmable, high-resolution PLL synthesizer
Fast frequency-hopping capability
High bit rate (up to 115.2 kbps in digital mode and 256 kbps
in analog mode)
Direct differential antenna input/output
Integrated power amplifier
Programmable TX frequency deviation (15 to 240 kHz)
Programmable RX baseband bandwidth (67 to 400 kHz)
Analog and digital RSSI outputs
Automatic frequency control (AFC)
Data quality detection (DQD)
Internal data filtering and clock recovery
RX synchron pattern recognition
SPI compatible serial control interface
Clock and reset signals for microcontroller
16-bit RX Data FIFO
Two 8-bit TX data registers
Low power duty cycle mode
Standard 10 MHz crystal reference with on-chip tuning
Wake-up timer
2.2 to 3.8 V supply voltage
Low power consumption
Low standby current (0.3 A)
Compact 16 pin TSSOP package
Supports very short packets (down to 3 bytes)
Excellent temperature stability of the RF parameters
Good adjacent channel rejection/blocking
TYPICAL APPLICATIONS
LBD
Controller
Bias
Low Power parts
8
9
15
1
2
CLK
XTL /
REF
ARSSI
SDI
SCK
3
4
nSEL SDO
5
10
16
11
14
nIRQ
nRES
nINT /
VDI
VSS
VDD
Home security and alarm
Remote control, keyless entry
Wireless keyboard/mouse and other PC peripherals
Toy controls
Remote keyless entry
Tire pressure monitoring
Telemetry
Personal/patient data logging
Remote automatic meter reading
1
Si4421-DS rev 2.4r 0708
www.silabs.com
Si4421
2
Si4421
DETAILED FEATURE-LEVEL DESCRIPTION
Full Baseband Amplifier Transfer Function
BW=67kHz
The Si4421 FSK transceiver is designed to cover the unlicensed
frequency bands at 433, 868 and 915 MHz. The device
facilitates compliance with FCC and ETSI requirements.
The receiver block employs the Zero-IF approach with I/Q
demodulation, allowing the use of a minimal number of external
components in a typical application. The Si4421 incorporates a
fully integrated multi-band PLL synthesizer, PA with antenna
tuning, an LNA with switchable gain, I/Q down converter mixers,
baseband filters and amplifiers, and an I/Q demodulator
followed by a data filter.
PLL
The programmable PLL synthesizer determines the operating
frequency, while preserving accuracy based on the on-chip crystalcontrolled reference oscillator. The PLL’s high resolution allows the
usage of multiple channels in any of the bands.
RF Power Amplifier (PA)
The power amplifier has an open-collector differential output and
can directly drive different PCB antennas with a programmable
output power level. An automatic antenna tuning circuit is built in
to avoid costly trimming procedures and the so-called “hand
effect”.
LNA
The LNA has approximately 250 Ohm input impedance, which
functions well with the proposed antennas (see: Application
Notes available from www.silabs.com/integration)
If the RF input of the chip is connected to 50 Ohm devices, an
external matching circuit is required to provide the correct
matching and to minimize the noise figure of the receiver.
The LNA gain can be selected in four steps (between 0 and
-20dB relative to the highest gain) according to RF signal
strength. It can be useful in an environment with strong
interferers.
Baseband Filters
Data Filtering and Clock Recovery
Output data filtering can be completed by an external capacitor
or by using digital filtering according to the final application.
Analog operation: The filter is an RC type low-pass filter followed
by a Schmitt-trigger (St). The resistor (10 kOhm) and the St are
integrated on the chip. An (external) capacitor can be chosen
according to the actual bit rate. In this mode, the receiver can
handle up to 256 kbps data rate. The FIFO cannot be used in this
mode and clock is not provided for the demodulated data.
Digital operation: A digital filter is used with a clock frequency at
29 times the bit rate. In this mode, there is a clock recovery
circuit (CR), which can provide synchronized clock to the data.
Using this clock the received data can fill a FIFO. The CR has
three operation modes: fast, slow, and automatic. In slow mode,
its noise immunity is very high, but it has slower settling time and
requires more accurate data timing than in fast mode. In
automatic mode, the CR automatically changes between fast and
slow mode. The CR starts in fast mode, then after locking, it
automatically switches to slow mode
(Only the digital data filter and the clock recovery use the bit rate
clock. For analog operation, there is no need for setting the
correct bit rate.)
The receiver bandwidth is selectable by programming the
bandwidth (BW) of the baseband filters. This allows setting up
the receiver according to the characteristics of the signal to be
received.
An appropriate bandwidth can be chosen to accommodate
various FSK deviation, data rate and crystal tolerance
requirements. The filter structure is 7th order Butterworth lowpass with 40 dB suppression at 2 · BW frequency. Offset
cancellation is done by using a high-pass filter with a cut-off
frequency below 7 kHz.
3
Si4421
Data Validity Blocks
RSSI
A digital RSSI output is provided to monitor the input signal level.
It goes high if the received signal strength exceeds a given
preprogrammed level. An analog RSSI signal is also available.
The RSSI settling time depends on the external filter capacitor.
Pin 15 is used as analog RSSI output. The digital RSSI can be
monitored by reading the status register.
Typical Analog ARSSI Voltage vs. RF Input Power
suggested to turn the output buffer off by the Power
Management Command (page 16).
Low Battery Voltage Detector
The low battery detector circuit monitors the supply voltage and
generates an interrupt if it falls below a programmable threshold
level. The detector circuit has 50 mV hysteresis.
Wake-Up Timer
The wake-up timer has very low current consumption (1.5 µA
typical) and can be programmed from 1 ms to several days with
an accuracy of ±10%.
The wake-up timer calibrates itself to the crystal oscillator at
every startup. For proper calibration of the wake-up timer the
crystal oscillator must be running before the wake-up timer is
enabled. The calibration process takes approximately 0.5ms.
For the crystal start up time (tsx), see page 12.
Event Handling
DQD
The operation of the Data Quality Detector is based on counting
the spikes on the unfiltered received data. High output signal
indicates an operating FSK transmitter within baseband filter
bandwidth from the local oscillator. DQD threshold parameter
can be set by using the Data Filter Command (page 20).
AFC
By using an integrated Automatic Frequency Control (AFC)
feature, the receiver can minimize the TX/RX offset in discrete
steps, allowing the use of:
Narrower receiver bandwidth (i.e. increased
sensitivity)
Higher data rate
Inexpensive crystals
Crystal Oscillator
The Si4421 has a single-pin crystal oscillator circuit, which
provides a 10 MHz reference signal for the PLL. To reduce
external parts and simplify design, the crystal load capacitor is
internal and programmable. Guidelines for selecting the
appropriate crystal can be found later in this datasheet.
The transceiver can supply a clock signal for the microcontroller;
so accurate timing is possible without the need for a second
crystal.
When the microcontroller turns the crystal oscillator off by
clearing the appropriate bit using the Power Management
Command (page 16), the chip provides a fixed number (192) of
further clock pulses (“clock tail”) for the microcontroller to let it
go to idle or sleep mode. If this clock output is not used, it is
In order to minimize current consumption, the transceiver
supports different power saving modes. Active mode can be
initiated by several wake-up events (negative logical pulse on
nINT input, wake-up timer timeout, low supply voltage detection,
on-chip FIFO filled up or receiving a request through the serial
interface).
If any wake-up event occurs, the wake-up logic generates an
interrupt signal, which can be used to wake up the
microcontroller,
effectively
reducing
the
period
the
microcontroller has to be active. The source of the interrupt can
be read out from the transceiver by the microcontroller through
the SDO pin.
Interface and Controller
An SPI compatible serial interface lets the user select the
frequency band, center frequency of the synthesizer, and the
bandwidth of the baseband signal path. Division ratio for the
microcontroller clock, wake-up timer period, and low supply
voltage detector threshold are also programmable. Any of these
auxiliary functions can be disabled when not needed. All
parameters are set to default after power-on; the programmed
values are retained during sleep mode. The interface supports
the read-out of a status register, providing detailed information
about the status of the transceiver and the received data.
The transmitter block is equipped with two 8-bit wide TX data
registers. It is possible to write 8 bits into the register in burst
mode and the internal bit rate generator transmits the bits out
with the predefined rate. For further details, see the TX Register
Buffered Data Transmission section (page 29).
It is also possible to store the received data bits into a FIFO
register and read them out in a buffered mode.
4
Si4421
PACKAGE PIN DEFINITIONS
Pin type key: D=digital, A=analog, S=supply, I=input, O=output, IO=input/output
Pin
Name
Type
1
SDI
DI
Data input of the serial control interface
2
SCK
DI
Clock input of the serial control interface
3
nSEL
DI
Chip select input of the serial control interface (active low)
4
SDO
DO
Serial data output with bus hold
5
nIRQ
DO
Interrupt request output (active low)
FSK
DI
Transmit FSK data input (internal pull up resistor 133 k)
DATA
DO
Received data output (FIFO not used)
nFFS
DI
FIFO select input (active low). In FIFO mode, when bit ef is set in Configuration Setting Command,
page 16 (internal pull up resistor 133 k)
DLCK
DO
Received data clock output (Digital filter used, FIFO not used)
CFIL
AIO
External data filter capacitor connection (Analog filter used)
6
7
8
Function
FFIT
DO
FIFO interrupt (active high). In FIFO mode, when bit ef is set in Configuration Setting Command
CLK
DO
Microcontroller clock output
XTL
AIO
Crystal connection (the other terminal of crystal to VSS) or external reference input
REF
AIO
External reference input. Use 33 pF series coupling capacitor
10
nRES
DIO
Open drain reset output with internal pull-up and input buffer (active low)
11
VSS
S
12
RF2
AIO
RF differential signal input/output
13
RF1
AIO
RF differential signal input/output
14
VDD
S
15
ARSSI
AO
nINT
DI
Interrupt input (active low)
VDI
DO
Valid data indicator output
9
16
Ground reference voltage
Positive supply voltage
Analog RSSI output
Note: The actual mode of the multipurpose pins (pin 6 and 7) is determined by the TX/RX data I/O settings of the transceiver.
5
Si4421
Internal Pin Connections
Pin
Name
1
SDI
2
SCK
3
nSEL
4
SDO
5
Internal connection
Pin
Name
10
nRES
11
VSS
12
RF2
13
RF1
14
VDD
15
ARSSI
Internal connection
nIRQ
FSK
6
DATA
nFFS
DLCK
7
CFIL
FFIT
VDD
8
CLK
nINT
16
PAD
10
VDI
VSS
XTL
9
REF
6
Si4421
PIN6 Logic Diagram (FSK / DATA / nFFS)
PIN10 Logic Diagram (nRES I/O)
* Note: These pins can be left floating.
7
Si4421
Typical Application
Typical application with FIFO usage
VDD
C1
2.2u
C3
P7
P6
P5
P4
P3
P2
P1
P0
CLKin
nRESin
VDI
(optional)
1
SDI
SCK
2
3
nSEL
SDO
nIRQ
nFFS (optional)*
FFIT (optional)*
(optional)
CLK
nRES
4
5
6
7
8
Si4421
(optional)
16
15
14
13
TP
C2
10n
C4
2.2n (opt.)
12
11
10
9
PCB
Antenna
X1
10MHz
Note: * Connections needed only in time critical applications
Recommended supply decoupling capacitor values
C2 and C3 should be 0603 size ceramic capacitors to achieve the best supply decoupling.
Band [MHz]
C1
C2
C3
Property
C1
C2
C3
433
2.2µF
10nF
220pF
SMD size
A
0603
0603
868
2.2µF
10nF
47pF
Dielectric
Tantalum
Ceramic
Ceramic
915
2.2µF
10nF
33pF
Pin Function vs. Operation Mode
Mode
Bit setting
Function
Pin 6
el = 0
Internal TX data register disabled
TX data input
el = 1
Internal TX data register enabled
nFFS input
(TX data register can be accessed)
ef = 0
Receiver FIFO disabled
RX data output
RX data clock
output
ef = 1
Receiver FIFO disabled
nFFS input
(RX data FIFO can be accessed)
FFIT output
Transmit
Receive
Pin 7
Not used
The el and ef bits can be found in the Configuration Setting Command on page 16. Bit el enables the internal TX data register.
Bit ef enables the FIFO mode.
8
Si4421
GENERAL DEVICE SPECIFICATIONS
All voltages are referenced to Vss, the potential on the ground reference pin VSS.
Absolute Maximum Ratings (non-operating)
Symbol
Parameter
Min
Max
Units
Vdd
Positive supply voltage
-0.5
6
V
Vin
Voltage on any pin (except RF1 and RF2)
-0.5
Vdd+0.5
V
Voc
Voltage on open collector outputs (RF1, RF2)
-0.5
Vdd+1.5 (Note 1)
V
Iin
Input current into any pin except VDD and VSS
-25
25
mA
ESD
Electrostatic discharge with human body model
Tst
Storage temperature
Tld
Lead temperature (soldering, max 10 s)
1000
-55
V
125
o
260
o
C
C
Recommended Operating Range
Symbol
Parameter
Min
Max
Units
Vdd
Positive supply voltage
2.2
3.8
V
Voc
Voltage range on open collector outputs (RF1, RF2)
Vdd-1.5 (Note 2)
Vdd+1.5
Top
Ambient operating temperature
-40
85
V
o
C
Note 1: The voltage on RF1 and RF2 pins can be higher than the actual Vdd but cannot exceed 7 V.
Note 2: The actual voltage on RF1 and RF2 pins can be lower than the current Vdd but never should go below 1.2 V.
9
Si4421
ELECTRICAL SPECIFICATION
Test Conditions: Top = 27 oC; Vdd = Voc = 3.3 V
DC Characteristics
Symbol
Idd_TX_0
Idd_TX_PMAX
Idd_RX
Parameter
Supply current
(TX mode, Pout = 0 dBm)
Supply current
(TX mode, Pout = Pmax)
Supply current (RX mode)
Ipd
Standby current (Sleep mode)
Ilb
Low battery voltage detector current
consumption
Conditions/Notes
868 MHz band
16
915 MHz band
17
22
26
27
915 MHz band
24
28
433 MHz band
11
13
868 MHz band
12
14
915 MHz band
13
15
All blocks disabled
0.3
1
µA
0.5
1.7
µA
Crystal oscillator on (Note 1)
Programmable in 0.1 V steps
Vil
Digital input low level voltage
Vih
Digital input high level voltage
Iil
mA
23
Wake-up timer current consumption
Low battery detect threshold
Units
868 MHz band
Idle current
Low battery detection accuracy
Max
433 MHz band
Ix
Vlb
Typ
15
Iwt
Vlba
Min
433 MHz band
1.5
3.5
µA
1.2
mA
3.75
±3
-1
-1
Iih
Digital input current
Vih = Vdd, Vdd = 3.8 V
Vol
Digital output low level
Iol = 2 mA
Voh
Digital output high level
Ioh = -2 mA
Vdd-0.4
V
%
0.3ꞏVdd
V
1
µA
1
µA
0.4
V
0.7ꞏVdd
Vil = 0 V
mA
0.6
2.25
Digital input current
mA
V
V
Notes are on page 13.
10
Si4421
AC Characteristics (PLL parameters)
Symbol
Parameter
Conditions/Notes
fref
PLL reference frequency
(Note 2)
Min
Typ
Max
Units
9
10
11
MHz
433 MHz band, 2.5 kHz resolution
430.24
439.75
fo
Receiver LO/Transmitter carrier
frequency
868 MHz band, 5.0 kHz resolution
860.48
879.51
915 MHz band, 7.5 kHz resolution
900.72
929.27
tlock
PLL lock time
Frequency error < 1kHz
after 10 MHz step
30
tstP
PLL startup time (Note 10)
With a running crystal oscillator
200
300
µs
Typ
Max
Units
MHz
µs
AC Characteristics (Receiver)
Symbol
BW
Parameter
Receiver bandwidth
Conditions/Notes
Min
mode 0
67
mode 1
134
mode 2
200
mode 3
270
mode 4
340
mode 5
kHz
400
BRRX
FSK bit rate (Note 10)
With internal digital filters
BRARX
FSK bit rate (Note 10)
With analog filter
0.6
-3
115.2
kbps
256
kbps
Pmin
Receiver Sensitivity
BER 10 , BW=67 kHz, BR=1.2 kbps,
868 MHz Band (Note 3)
AFCrange
AFC locking range
δfFSK: FSK deviation in the received
signal
IIP3inh
Input IP3
In band interferers in high bands
(868 MHz, 915 MHz)
-21
dBm
IIP3outh
Input IP3
Out of band interferers l f-fo l > 4 MHz
-18
dBm
IIP3inl
IIP3 (LNA –6 dB gain)
In band interferers in low band (433
MHz)
-15
dBm
IIP3outl
IIP3 (LNA –6 dB gain)
Out of band interferers l f-fo l > 4 MHz
Pmax
Maximum input power
LNA: high gain
Cin
RF input capacitance
RSa
RSSI accuracy
±6
dB
RSr
RSSI range
46
dB
RSps
RSSI power supply dependency
+35
mV/V
6
dB
500
µs
CARSSI
Filter capacitor for ARSSI
RSstep
RSSI programmable level steps
RSresp
DRSSI response time
Psp
Receiver spurious emission
rx
-110
dBm
0.8ꞏδfFSK
-12
dBm
0
dBm
1
When input signal level lower than -54
dBm and greater than -100 dBm
pF
1
Until the RSSI signal goes high after
the input signal exceeds the
preprogrammed limit CARRSI = 4.7 nF
nF
-60
dBm
Notes are on page 13.
11
Si4421
AC Characteristics (Transmitter)
Symbol
Parameter
Conditions/Notes
Min
Open collector output DC current
Programmable
0.5
Pmax_50
Max. output power delivered to 50
Ohm load over a suitable matching
network (Note 4)
In 433 MHz band
7
In 868 MHz / 915 MHz bands
5
Pmax_ant
Max. EIRP with suitable selected
PCB antenna (Note 6)
In 433 MHz band with monopole antenna
with matching network (Note 4)
7
In 868 MHz / 915 MHz bands (Note 5)
7
IOUT
Typ
Units
6
mA
dBm
dBm
Pout
Typical output power
Selectable in 2.5 dB steps (Note 7)
Psp
Spurious emission
l f-fsp l > 1 MHz
At max power 50 Ohm load (Note 4)
-55
With PCB antenna (Note 5)
-60
Pharm
Harmonic suppression
Pmax-17.5
Max
Pmax
At max power 50 Ohm load (Note 4)
-35
With PCB antenna (Note 5)
-42
Co
Output capacitance (set by the
automatic antenna tuning circuit)
In 433 MHz band
2
2.6
3.2
In 868 MHz / 915 MHz bands
2.1
2.7
3.3
Qo
Quality factor of the output
capacitance
In 433 MHz band
13
15
17
In 868 MHz / 915 MHz bands
8
10
12
Lout
Output phase noise
100 kHz from carrier, in 868 MHz band
-80
1 MHz from carrier, in 868 MHz band
-103
dBm
dBc
dBc
pF
dBc/Hz
BRTX
FSK bit rate
Via internal TX data register
172
kbps
BRATX
FSK bit rate
TX data connected to the FSK input
256
kbps
FSK frequency deviation
Programmable in 15 kHz steps
240
kHz
dffsk
15
AC Characteristics (Turn-on/Turnaround timings)
Symbol
Parameter
Conditions/Notes
Typ
Max
Units
Crystal oscillator startup time
Default capacitance bank setting, crystal
ESR < 50 Ohm (Note 9). Crystal load
capacitance = 16 pF.
2
7
ms
Ttx_XTAL_ON
Transmitter turn-on time
Synthesizer off, crystal oscillator on with
10 MHz step
250
µs
Trx_XTAL_ON
Receiver turn-on time
Synthesizer off, crystal oscillator on with
10 MHz step
250
µs
Ttx_rx_SYNT_ON
Transmitter – Receiver turnover time
Synthesizer and crystal oscillator on
during TX/RX change with 10 MHz step
150
µs
Trx_tx_SYNT_ON
Receiver – Transmitter turnover time
Synthesizer and crystal oscillator on
during RX/TX change with 10 MHz step
150
µs
tsx
Min
AC Characteristics (Others)
Symbol
Parameter
Conditions/Notes
Min
Cxl
Crystal load capacitance,
see crystal selection guide
Programmable in 0.5 pF steps, tolerance
± 10%
8.5
tPOR
Internal POR timeout
After Vdd has reached 90% of final value
(Note 8)
tPBt
Wake-up timer clock accuracy
Crystal oscillator must be enabled to
ensure proper calibration at the start up.
(Note 9)
CinD
Digital input capacitance
tr, tf
Digital output rise/fall time
15 pF pure capacitive load
Typ
Max
Units
16
pF
100
ms
± 10
%
2
pF
10
ns
Notes are on page 13.
12
Si4421
Note 1: Measured with disabled clock output buffer
Note 2: Not using a 10 MHz crystal is allowed but not recommended because all crystal referred timing and frequency parameters
will change accordingly
Note 3: See the BER diagrams in the measurement results section (page 38) for detailed information
Note 4: See reference design with 50 Ohm Matching Network (page 40) for details
Note 5: See reference design with Resonant PCB Antenna (BIFA) on page 42 for details
Note 6: Optimal antenna admittance/impedance:
Si4421
Yantenna [mS]
Zantenna [Ohm]
Lantenna [nH]
2 – j5.9
52 + j152
62
868 MHz
1.2 - j11.9
7.8 + j83
15.4
915 MHz
1.49 - j12.8
9 + j77
13.6
433 MHz
Note 7: Adjustable in 8 steps
Note 8: During the Power-On Reset period, commands are not accepted by the chip. In case of software reset (see Wake-Up Timer
Command, page 26) the reset timeout is 0.25ms typical.
Note 9: The crystal oscillator start up time strongly depends on the capacitance seen by the oscillator. Low capacitance and low
ESR crystal is recommended with low parasitic PCB layout design.
Note 10: By design
13
Si4421
CONTROL INTERFACE
Commands to the transmitter are sent serially. Data bits on pin SDI are shifted into the device upon the rising edge of the clock on
pin SCK whenever the chip select pin nSEL is low. When the nSEL signal is high, it initializes the serial interface. All commands
consist of a command code, followed by a varying number of parameter or data bits. All data are sent MSB first (e.g. bit 15 for a 16bit command). Bits having no influence (don’t care) are indicated with X. Special care must be taken when the microcontroller’s builtin hardware serial port is used. If the port cannot be switched to 16-bit mode then a separate I/O line should be used to control the
nSEL pin to ensure the low level during the whole duration of the command or a software serial control interface should be
implemented. The Power-On Reset (POR) circuit sets default values in all control and command registers.
The receiver will generate an interrupt request (IT) for the microcontroller - by pulling the nIRQ pin low - on the following events:
The TX register is ready to receive the next byte (RGIT)
The RX FIFO has received the preprogrammed amount of bits (FFIT)
Power-on reset (POR)
RX FIFO overflow (FFOV) / TX register underrun (RGUR)
Wake-up timer timeout (WKUP)
Negative pulse on the interrupt input pin nINT (EXT)
Supply voltage below the preprogrammed value is detected (LBD)
FFIT and FFOV are applicable when the RX FIFO is enabled. RGIT and RGUR are applicable only when the TX register is enabled. To
identify the source of the IT, the status bits should be read out.
Timing Specification
Symbol
Parameter
Minimum value [ns]
tCH
Clock high time
25
tCL
Clock low time
25
tSS
Select setup time (nSEL falling edge to SCK rising edge)
10
tSH
Select hold time (SCK falling edge to nSEL rising edge)
10
tSHI
Select high time
25
tDS
Data setup time (SDI transition to SCK rising edge)
5
tDH
Data hold time (SCK rising edge to SDI transition)
5
tOD
Data delay time
10
Timing Diagram
tSHI
tSS
nSEL
tCH
tOD
tCL
tSH
SCK
tDS
tDH
SDI
BIT 15
SDO
FFIT
BIT 14
FFOV
BIT 13
BIT 8
CRL
BIT 7
AT S
BIT 1
OFFS(0)
BIT 0
FIFO OUT
14
Si4421
Control Commands
Control Command
Related Parameters/Functions
Related control bits
1
Configuration Setting Command
Frequency band, crystal oscillator load capacitance,
RX FIFO and TX register enable
el, ef, b1 to b0, x3 to x0
2
Power Management Command
Receiver/Transmitter mode change, synthesizer,
crystal oscillator, PA, wake-up timer, clock output
enable
er, ebb, et, es, ex, eb, ew, dc
3
Frequency Setting Command
Frequency of the local oscillator/carrier signal
f11 to f0
4
Data Rate Command
Bit rate
cs, r6 to r0
5
Receiver Control Command
Function of pin 16, Valid Data Indicator, baseband
bandwidth, LNA gain, digital RSSI threshold
p16, d1 to d0, i2 to i0, g1 to g0, r2
to r0
6
Data Filter Command
Data filter type, clock recovery parameters
al, ml, s, f2 to f0
FIFO and Reset Mode Command
Data FIFO IT level, FIFO start control, FIFO enable
and FIFO fill enable, POR sensitivity
f3 to f0, sp, ff, al, dr
8
Synchron Pattern Command
Synchron pattern
b7 to b0
9
Receiver FIFO Read Command
RX FIFO read
10
AFC Command
AFC parameters
a1 to a0, rl1 to rl0, st, fi, oe, en
11
TX Configuration Control Command
Modulation parameters, output power
mp, m3 to m0, p2 to p0
12
PLL Setting Command
CLK out buffer speed, dithering, PLL bandwidth
ob1 to ob0, ddit, dly, bw0
13
Transmitter Register Write Command
TX data register write
t7 to t0
14
Wake-Up Timer Command
Wake-up time period
r4 to r0, m7 to m0
15
Low Duty-Cycle Command
Enable and set low duty-cycle mode
d6 to d0, en
16
Low Battery Detector and
Microcontroller Clock Divider
Command
LBD voltage and microcontroller clock division ratio
d2 to d0, v3 to v0
17
Status Read Command
Status bit readout
7
In general, setting the given bit to one will activate the related function. In the following tables, the POR column shows the default
values of the command registers after power-on.
Control Register Default Values
Control Register
Power-On Reset Value
1
Configuration Setting Command
8008h
2
Power Management Command
8208h
3
Frequency Setting Command
A680h
4
Data Rate Command
C623h
5
Receiver Control Command
9080h
6
Data Filter Command
C22Ch
7
FIFO and Reset Mode Command
CA80h
8
Synchron Pattern Command
CED4h
9
Receiver FIFO Read Command
B000h
10
AFC Command
C4F7h
11
TX Configuration Control Command
9800h
12
PLL Setting Command
CC77h
13
Transmitter Register Write Command
B8AAh
14
Wake-Up Timer Command
E196h
15
Low Duty-Cycle Command
C80Eh
16
Low Battery Detector and Microcontroller Clock Divider Command
C000h
17
Status Read Command
0000h
15
Si4421
Description of the Control Commands
1. Configuration Setting Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
0
0
0
0
0
0
0
el
ef
b1
b0
x3
x2
x1
x0
8008h
Bit el enables the internal data register.
Bit ef enables the FIFO mode. If ef = 0 then DATA (pin 6) and DCLK (pin 7) are used for data and data clock output.
b1
0
0
1
1
x3
0
0
0
0
Frequency Band
Reserved
433
868
915
b0
0
1
0
1
x2
0
0
0
0
x1
0
0
1
1
x0
0
1
0
1
Crystal Load Capacitance [pF]
8.5
9.0
9.5
10.0
…
1
1
1
1
1
1
0
1
15.5
16.0
2. Power Management Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
0
0
0
0
0
1
0
er
ebb
et
es
ex
eb
ew
dc
8208h
Bit
Function of the control bit
Related blocks
er
Enables the whole receiver chain
RF front end, baseband, synthesizer, crystal oscillator
The receiver baseband circuit can be separately switched on
Baseband
et
Switches on the PLL, the power amplifier, and starts the
transmission (If TX register is enabled)
Power amplifier, synthesizer, crystal oscillator
es
Turns on the synthesizer
Synthesizer
ex
Turns on the crystal oscillator
Crystal oscillator
ebb
eb
Enables the low battery detector
Low battery detector
ew
Enables the wake-up timer
Wake-up timer
dc
Disables the clock output (pin 8)
Clock output buffer
The ebb, es, and ex bits are provided to optimize the TX to RX or RX to TX turnaround time.
The RF frontend consist of the LNA (low noise amplifier) and the mixer. The synthesizer block has two main components: the VCO
and the PLL. The baseband section contains the baseband amplifier, low pass filter, limiter and the I/Q demodulator.
To decrease TX/RX turnaround time, it is possible to leave the baseband section powered on. Switching to RX mode means disabling
the PA and enabling the RF frontend. Since the baseband block is already on, the internal startup calibration will not be performed,
the turnaround time will be shorter.
The synthesizer also has an internal startup calibration procedure. If quick RX/TX switching needed it may worth to leave this block
on. Enabling the transmitter using the et bit will turn on the PA, the synthesizer is already up and running. The power amplifier almost
immediately produces TX signal at the output.
The crystal oscillator provides reference signal to the RF synthesizer, the baseband circuits and the digital signal processor part.
When the receiver or the transmitter part frequently used, it is advised to leave the oscillator running because the crystal might need
a few milliseconds to start. This time mainly depends on the crystal parameters.
It is important to note that leaving blocks unnecessary turned on can increase the current consumption thus decreasing the battery
life.
16
Si4421
Logic connections between power control bits:
enable
power amplifier
et
start TX
Edge
detector
enable
power amplifier
enable
RF front end
clear TX latch
es
enable
RF synthesizer
er
enable
RF front end
enable
RF synthesizer
VCO and
PLL
start TX
clear TX latch
enable
crystal oscillator
enable baseband
circuits
TX latch
Crystal
oscillator
enable baseband
circuits
I/Q
demod
ebb
Digital signal
processing
enable crystal
oscillator
ex
clock and data out
Note:
If both et and er bits are set the chip goes to receive mode.
FSK / nFFS input are equipped with internal pull-up resistor. To achieve minimum current consumption do not pull this input
to logic low in sleep mode.
To enable the RF synthesizer, the crystal oscillator must be turned on
To turn on the baseband circuits, the RF synthesizer (and this way the crystal oscillator) must be enabled.
Setting the er bit automatically turns on the crystal oscillator, the synthesizer, the baseband circuits and the RF fronted.
Setting the et bit automatically turns on the crystal oscillator, the synthesizer and the RF power amplifier.
Clock tail feature: When the clock output (pin 8) used to provide clock signal for the microcontroller (dc bit is set to 0), it is possible
to use the clock tail feature. This means that the crystal oscillator turn off is delayed, after issuing the command (clearing the ex bit)
192 more clock pulses are provided. This ensures that the microcontroller can switch itself to low power consumption mode. In order
to use this feature, a Status Read Command (page 28) must be issued before the ex bit set to zero. If status read was not performed
then the clock output shuts down immediately leaving the microcontroller in unknown state.
Automatic crystal oscillator enable/disable feature: When an interrupt occurs, the crystal oscillator automatically turns on –
regardless to the setting of the ex bit – to supply clock signal to the microcontroller. After clearing all interrupts by handling them
properly (see the Interrupt Handling section, page 29) and performing Status Read Command, the crystal oscillator is automatically
turned off. The clock tail feature provides enough clock pulses for the microcontroller to go to low power mode. Due to this automatic
feature, it is not possible to turn off the crystal by clearing the ex bit if any interrupt is active. For example, after power on the POR
interrupt must be cleared by a status read then writing zero to the ex bit will put the part into sleep mode. Very important to clear all
interrupts before turning the ex bit off because the extra current required by running crystal oscillator can shorten the battery life
significantly.
Disabling the clock output (bit dc=1) turns off both the clock tail and the automatic crystal oscillator enable/disable feature, only the
ex bit controls the crystal oscillator (supposing that both the er and et bits are cleared), the interrupts have no effect on it.
17
Si4421
3. Frequency Setting Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
0
1
0
f11
f10
f9
f8
f7
f6
f5
f4
f3
f2
f1
f0
A680h
The constants C1 and C2 are determined by
the selected band as:
The 12-bit parameter F (bits f11 to f0) should be in the range
of 96 and 3903. When F value sent is out of range, the
previous value is kept. The synthesizer center frequency f0 can
be calculated as:
Band [MHz]
C1
C2
433
1
43
868
2
43
915
3
30
f0 = 10 · C1 · (C2 + F/4000) [MHz]
Band
Minimum Frequency
Maximum Frequency
PLL Frequency Step
433 MHz
430.2400 MHz
439.7575 MHz
2.5 kHz
868 MHz
860.4800 MHz
879.5150 MHZ
5.0 kHz
915 MHz
900.7200 MHz
929.2725 MHz
7.5 kHz
4. Data Rate Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
1
0
0
0
1
1
0
cs
r6
r5
r4
r3
r2
r1
r0
C623h
The actual bit rate in transmit mode and the expected bit rate of the received data stream in receive mode is determined by the 7-bit
parameter R (bits r6 to r0) and bit cs.
BR = 10000 / 29 / (R+1) / (1+cs · 7) [kbps]
In the receiver set R according to the next function:
R= (10000 / 29 / (1+cs · 7) / BR) – 1, where BR is the expected bit rate in kbps.
Apart from setting custom values, the standard bit rates from 600 bps to 115.2 kbps can be approximated with small error.
Data rate accuracy requirements:
Clock recovery in slow mode: BR/BR < 1/(29 · Nbit)
Clock recovery in fast mode: BR/BR < 3/(29 · Nbit)
BR is the bit rate set in the receiver and BR is the bit rate difference between the transmitter and the receiver. Nbit is the maximum
number of consecutive ones or zeros in the data stream. It is recommended for long data packets to include enough 1/0 and 0/1
transitions, and to be careful to use the same division ratio in the receiver and in the transmitter.
5. Receiver Control Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
0
0
1
0
p16
d1
d0
i2
i1
i0
g1
g0
r2
r1
r0
9080h
Bit 10 (p16):
Pin 16 function select
p16
0
1
Function of pin 16
Interrupt input
VDI output
18
Si4421
Bits 9-8 (d1 to d0):
VDI (valid data indicator) signal response time setting:
d1
0
0
1
1
Response
Fast
Medium
Slow
Always on
d0
0
1
0
1
VDI Logic Diagram:
MUX
DQD
CR_LOCK
d0
d1
DRSSI
MEDIUM
SEL0
SEL1
FAST
SLOW
DQD
LOGIC HIGH
IN0
IN1
Y
VDI
IN2
IN3
CLR
DRSSI
DQD
CR_LOCK
SET
Q
er *
R/S FF
CLR
Note:
* For details see the Power Management Command
Slow mode: The VDI signal will go high only if the DRSSI, DQD and the CR_LOCK (Clock Recovery Locked) signals present at the same
time. It stays high until any of the abovementioned signals present; it will go low when all the three input signals are low.
Medium mode: The VDI signal will be active when the CR_LOCK signal and either the DRSSI or the DQD signal is high. The valid data
indicator will go low when either the CR_LOCK gets inactive or both of the DRSSI or DQD signals go low.
Fast mode: The VDI signal follows the level of the DQD signal.
Always mode: VDI is connected to logic high permanently. It stays always high independently of the receiving parameters.
Bits 7-5 (i2 to i0):
Receiver baseband bandwidth (BW) select:
i2
0
0
0
0
1
1
1
1
i1
0
0
1
1
0
0
1
1
i0
0
1
0
1
0
1
0
1
BW [kHz]
Reserved
400
340
270
200
134
67
Reserved
Note: For the optimal bandwidth settings at different data rates see the table on page 38.
19
Si4421
Bits 4-3 (g1 to g0):
LNA gain select:
g1
0
0
1
1
Bits 2-0 (r2 to r0):
Gain relative to maximum [dB]
0
-6
-14
-20
g0
0
1
0
1
RSSI detector threshold:
r2
0
0
0
0
1
1
1
1
r1
0
0
1
1
0
0
1
1
RSSIsetth [dBm]
-103
-97
-91
-85
-79
-73
Reserved
Reserved
r0
0
1
0
1
0
1
0
1
The RSSI threshold depends on the LNA gain, the real RSSI threshold can be calculated:
RSSIth=RSSIsetth+GLNA
6. Data Filter Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
1
0
0
0
0
1
0
al
ml
1
s
1
f2
f1
f0
C22Ch
Bit 7 (al): Clock recovery (CR) auto lock control
1: auto mode: the CR starts in fast mode, after locking it switches to slow mode. Bit 6 (ml) has no effect.
0: manual mode, the clock recovery mode is set by Bit 6 (ml)
Bit 6 (ml): Clock recovery lock control
1: fast mode, fast attack and fast release (4 to 8-bit preamble (1010...) is recommended)
0: slow mode, slow attack and slow release (12 to 16-bit preamble is recommended)
Using the slow mode requires more accurate bit timing (see Data Rate Command, page 18).
Bit 4 (s):
Select the type of the data filter:
Filter Type
Digital filter
Analog RC filter
s
0
1
Digital: This is a digital realization of an analog RC filter followed by a comparator with hysteresis. The time
constant is automatically adjusted to the bit rate defined by the Data Rate Command (page 18).
Note: Bit rate cannot exceed 115 kpbs in this mode.
Analog RC filter: The demodulator output is fed to pin 7 over a 10 kOhm resistor. The filter cut-off frequency is set
by the external capacitor connected to this pin and VSS.
The table shows the optimal filter capacitor values for different data rates
Data Rate [kbps]
1.2
2.4
4.8
9.6
19.2
38.4
57.6
115.2
256
Filter Capacitor Value
12 nF
8.2 nF
6.8 nF
3.3 nF
1.5 nF
680 pF
270 pF
150 pF
100 pF
Note: If analog RC filter is selected the internal clock recovery circuit and the FIFO cannot be used.
20
Si4421
Bits 2-0 (f2 to f0):
DQD threshold parameter.
The Data Quality Detector is a digital processing part of the radio, connected to the demodulator - it is an indicator
reporting the reception of an FSK modulated RF signal. It will work every time the receiver is on. Setting this
parameter defines how clean incoming data stream would be stated as good data (valid FSK signal).
If the internally calculated data quality value exceeds the DQD threshold parameter for five consecutive data bits
for both the high and low periods, then the DQD signal goes high.
The DQD parameter in the Data Filter Command should be chosen according to the following rules:
The DQD parameter can be calculated with the following formula:
DQDpar = 4 x (deviation – TX-RXoffset) / bit rate
It should be larger than 4 because otherwise noise might be treated as a valid FSK signal
The maximum value is 7.
7. FIFO and Reset Mode Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
1
0
0
1
0
1
0
f3
f2
f1
f0
sp
al
ff
dr
CA80h
Bits 7-4 (f3 to f0):
FIFO IT level. The FIFO generates IT when the number of received data bits reaches this level.
Bit 3 (sp):
Select the length of the synchron pattern:
sp
0
1
Byte1
2Dh
Not used
Byte0 (POR)
D4h
D4h
Synchron Pattern (Byte1+Byte0)
2DD4h
D4h
Note: The synchron pattern consists of one or two bytes depending on the sp bit. Byte1 is fixed 2Dh, Byte0 can be programmed by
the Synchron Pattern Command (page 22).
Bit 2 (al):
Set the input of the FIFO fill start condition:
al
0
1
FIFO fill start condition
Synchron pattern
Always fill
21
Si4421
Bit 1 (ff):
FIFO fill will be enabled after synchron pattern reception. The FIFO fill stops when this bit is cleared.
Bit 0 (dr): Disables the highly sensitive RESET mode.
dr
Reset mode
Reset triggered when
0
Sensitive reset
Vdd below 1.6V, Vdd glitch greater than 600mV
1
Non-sensitive reset
Vdd below 250mV
Note: To restart the synchron pattern recognition, bit 1 (ef, FIFO fill enable) should be cleared and set.
8. Synchron Pattern Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
1
0
0
1
1
1
0
b7
b6
b5
b4
b3
b2
b1
b0
CED4h
The Byte0 of the synchron pattern (see FIFO and Reset Mode command, page 21) can be reprogrammed by B .
9. Receiver FIFO Read Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
B000h
With this command, the controller can read 8 bits from the receiver FIFO. Bit 6 (ef) must be set in Configuration Setting Command
(page 16).
Note: During FIFO access fSCK cannot be higher than fref /4, where fref is the crystal oscillator frequency. When the duty-cycle of the
clock signal is not 50 % the shorter period of the clock pulse width should be at least 2/fref.
10. AFC Command
Bit
15
1
14
1
Bit 7-6 (a1 to a0):
13
0
12
0
11
0
10
1
9
0
8
0
7
a1
6
a0
5
rl1
4
rl0
3
st
2
fi
1
oe
0
en
POR
C4F7h
Automatic operation mode selector:
a1
0
0
1
1
a0
0
1
0
1
Operation mode
Auto mode off (Strobe is controlled by microcontroller)
Runs only once after each power-up
Keep the foffset only during receiving (VDI=high)
Keep the foffset value independently from the state of the VDI signal
22
Si4421
Bit 5-4 (rl1 to rl0):
Range limit. Limits the value of the frequency offset register to the next values:
rl1
0
0
1
1
rl0
0
1
0
1
Max deviation
No restriction
+15 fres to -16 fres
+7 fres to -8 fres
+3 fres to -4 fres
fres:
433 MHz bands: 2.5 kHz
868 MHz band: 5 kHz
915 MHz band: 7.5 kHz
Bit 3 (st):
Strobe edge, when st goes to high, the actual latest calculated frequency error is stored into the offset register of
the AFC block.
Bit 2 (fi):
Switches the circuit to high accuracy (fine) mode. In this case, the processing time is about twice as long, but the
measurement uncertainty is about half.
Bit 1 (oe):
Enables the frequency offset register. It allows the addition of the offset register to the frequency control word of
the PLL.
Bit 0 (en):
Enables the calculation of the offset frequency by the AFC circuit.
In manual mode, the strobe signal is provided by the microcontroller. One measurement cycle (and strobe) signal can compensate
about 50-60% of the actual frequency offset. Two measurement cycles can compensate 80%, and three measurement cycles can
compensate 92%. The ATGL bit in the status register can be used to determine when the actual measurement cycle is finished.
In automatic operation mode (no strobe signal is needed from the microcontroller to update the output offset register) the AFC circuit
is automatically enabled when the VDI indicates potential incoming signal during the whole measurement cycle and the circuit
measures the same result in two subsequent cycles.
Without AFC the transmitter and the receiver needs to be tuned precisely to the same frequency. RX/TX frequency offset can lower
the range. The units must be adjusted carefully during production, stable, expensive crystal must be used to avoid drift or the output
power needs to be increased to compensate yield loss.
The AFC block will calculate the TX-RX offset. This value will be used to pull the RX synthesizer close to the frequency of the
transmitter. The main benefits of the automatic frequency control: cheap crystal can be used, the temperature or aging drift will not
cause range loss and no production alignment needed.
23
Si4421
There are four operation modes:
1. (a1=0, a0=0) Automatic operation of the AFC is off. Strobe bit can be controlled by the microcontroller.
2. (a1=0, a0=1) The circuit measures the frequency offset only once after power up. This way, extended TX-RX distance can be
achieved. In the final application, when the user inserts the battery, the circuit measures and compensates for the frequency offset
caused by the crystal tolerances. This method allows for the use of cheaper quartz in the application and provides protection against
tracking an interferer.
3. (a1=1, a0=0) The frequency offset is calculated automatically and the center frequency is corrected when the VDI is high. The
calculated value is dropped when the VDI goes low. To improve the efficiency of the AFC calculation two methods are recommended:
a. The transmit package should start with a low effective baud rate pattern (i.e.: 00110011) because it is easier to receive. The
circuit automatically measures the frequency offset during this initial pattern and changes the receiving frequency accordingly.
The further part of the package will be received by the corrected frequency settings.
b. The transmitter sends the first part of the packet with a step higher deviation than required during normal operation to ease
the receiving. After the frequency shift was corrected, the deviation can be reduced.
In both cases (3a and 3b), when the VDI indicates poor receiving conditions (VDI goes low), the output register is automatically
cleared. Use this “drop offset” mode when the receiver communicates with more than one transmitter.
4. (a1=1, a0=1) It is similar to mode 3, but suggested to use when a receiver operates with only one transmitter. After a complete
measuring cycle, the measured value is kept independently of the state of the VDI signal. When the receiver is paired with only one
transmitter, it is possible to use this “keep offset” mode. In this case, the DRSSI limit should be selected carefully to minimize the
range hysteresis.
11. TX Configuration Control Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
0
0
1
1
0
0
mp
m3
m2
m1
m0
0
p2
p1
p0
9800h
Bits 8-4 (mp, m3 to m0): FSK modulation parameters:
The resulting output frequency can be calculated as:
P out
fout = f0 + (-1)SIGN · (M + 1) · (15 kHz)
where:
df fsk
f0 is the channel center frequency (see the
Frequency Setting Command)
M is the four bit binary number
SIGN = (mp) XOR FSK
Note:
f0
For the optimal FSK modulation settings at different
data rates see the table on page 38.
mp=0 and FSK=0
or
mp=1 and FSK=1
Bits 2-0 (p2 to p0): Output power:
Note:
df fsk
f out
mp=0 and FSK=1
or
mp=1 and FSK=0
Relative Output Power [dB]
p2
p1
p0
0
0
0
0
0
0
1
-2.5
0
1
0
-5
0
1
1
-7.5
1
0
0
1
0
1
-12.5
1
1
0
-15
1
1
1
-17.5
Note:
FSK represents the value of the actual data bit.
-10
The output power given in the table is relative to the
maximum available power, which depends on the
actual antenna impedance. (See: Antenna
Application Note: IA ISM-AN1)
24
Si4421
12. PLL Setting Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
1
0
0
1
1
0
0
0
ob1
ob0
1
dly
ddit
1
bw0
CC77h
Bits 6-5 (ob1-ob0):
Microcontroller output clock buffer rise and fall time control. The ob1-ob0 bits are changing the output drive
current of the CLK pin. Higher current provides faster rise and fall times but can cause interference.
ob1
ob0
Selected µC CLK frequency
1
1
5 or 10 MHz (recommended)
1
0
3.3 MHz
0
X
2.5 MHz or less
Note: Needed for optimization of the RF performance. Optimal settings can vary according to the external load capacitance.
Bit 3 (dly): Switches on the delay in the phase detector when this bit is set.
Bit 2 (ddit): When set, disables the dithering in the PLL loop.
Bit 0 (bw0):
PLL bandwidth can be set for optimal TX RF performance.
bw0
Max bit rate [kbps]
0
86.2
Phase noise at 1MHz offset [dBc/Hz]
-107
1
256
-102
Note: POR default settings of the register were carefully selected to cover almost all typical applications. When changing these
values, examine thoroughly the output RF spectrum. For more information, contact Silicon Labs Support.
13. Transmitter Register Write Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
0
1
1
1
0
0
0
t7
t6
t5
t4
t3
t2
t1
t0
B8AAh
With this command, the controller can write 8 bits (t7 to t0) to the transmitter data register. Bit 7 (el) must be set in Configuration
Setting Command (page 16).
Multiple Byte Write with Transmit Register Write Command:
nSEL
SCK
SDI
TX BYTE1
TX BYTE2
TX BYTEn
Transmit Register Write
command
SDO
(REGISTER IT
in TX mode*)
Note: *The transceiver is in transmit (TX) mode when bit er is cleared using the Power Management Command
Note: Alternately the transmit register can be directly accessed by nFFS (pin6).
25
Si4421
14. Wake-Up Timer Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
1
1
r4
r3
r2
r1
r0
m7
m6
m5
m4
m3
m2
m1
m0
E196h
The wake-up time period can be calculated by (m7 to m0) and (r4 to r0):
Twake-up = 1.03 · M · 2R + 0.5 [ms]
Note:
For continual operation, the ew bit should be cleared and set at the end of every cycle.
For future compatibility, use R in a range of 0 and 29.
15. Low Duty-Cycle Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
1
0
0
1
0
0
0
d6
d5
d4
d3
d2
d1
d0
en
C80Eh
With this command, autonomous low duty-cycle operation can be set in order to decrease the average power consumption in receive
mode.
Bits 7-1 (d6-d0):
The duty-cycle can be calculated by using (d6 to d0) and M. (M is parameter in a Wake-Up Timer Command, see
above). The time cycle is determined by the Wake-Up Timer Command.
duty-cycle= (D · 2 +1) / M · 100%
Bit 0 (en): Enables the low duty-cycle Mode. Wake-up timer interrupt is not generated in this mode.
Note: In this operation mode, bit er must be cleared and bit ew must be set in the Power Management Command (page 16).
In low duty-cycle mode the receiver periodically wakes up for a short period of time and checks if there is a valid FSK transmission in
progress. FSK transmission is detected in the frequency range determined by Frequency Setting Command (page 18) plus and
minus the baseband filter bandwidth determined by the Receiver Control Command (page 18). This on-time is automatically
extended while DQD indicates good received signal condition.
When calculating the on-time take into account:
-
the crystal oscillator, the synthesizer and the PLL needs time to start, see the AC Characteristics (Turn-on/Turnaround
timings) on page 12
-
depending on the DQD parameter, the chip needs to receive a few valid data bits before the DQD signal indicates good
signal condition (Data Filter Command, page 20)
Choosing too short on-time can prevent the crystal oscillator from starting or the DQD signal will not go high even when the received
signal has good quality.
There is an application proposal on page 27. The Si4421 is configured to work in FIFO mode. The chip periodically wakes up and
switches to receiving mode. If valid FSK data received, the chip sends an interrupt to the microcontroller and continues filling the RX
FIFO. After the transmission is over and the FIFO is read out completely and all other interrupts are cleared, the chip goes back to low
power consumption mode.
26
Si4421
Application Proposal for LPDM (Low Power Duty-Cycle Mode) Receivers:
16. Low Battery Detector and Microcontroller Clock Divider Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
1
1
0
0
0
0
0
0
d2
d1
d0
0
v3
v2
v1
v0
C000h
The 4-bit parameter (v3 to v0) represents the value V, which defines the threshold voltage Vlb of the detector:
Vlb= 2.25 + V · 0.1 [V]
Clock divider configuration:
d2
d1
d0
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
Clock Output
Frequency [MHz]
1
1.25
1.66
2
2.5
3.33
5
10
The low battery detector and the clock output can be enabled or disabled by bits eb and dc, respectively, using the Power
Management Command (page 16).
27
Si4421
17. Status Read Command
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POR
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0000h
The read command starts with a zero, whereas all other control commands start with a one. If a read command is identified, the
status bits will be clocked out on the SDO pin as follows:
Status Register Read Sequence with FIFO Read Example:
Bit Name
Function
RGIT
TX register is ready to receive the next byte (Can be cleared by Transmitter Register Write Command, page 25)
FFIT
The number of data bits in the RX FIFO has reached the pre-programmed limit (Can be cleared by any of the
FIFO read methods)
POR
Power-on reset (Cleared after Status Read Command)
RGUR
TX register under run, register over write (Cleared after Status Read Command)
FFOV
RX FIFO overflow (Cleared after Status Read Command)
WKUP
Wake-up timer overflow (Cleared after Status Read Command)
EXT
Logic level on interrupt pin (pin 16) changed to low (Cleared after Status Read Command)
LBD
Low battery detect, the power supply voltage is below the pre-programmed limit
FFEM
FIFO is empty
ATS
Antenna tuning circuit detected strong enough RF signal
RSSI
The strength of the incoming signal is above the pre-programmed limit
DQD
Data quality detector output
CRL
Clock recovery locked
ATGL
OFFS(6)
OFFS(3) -OFFS(0)
Toggling in each AFC cycle
MSB of the measured frequency offset (sign of the offset value)
Offset value to be added to the value of the frequency control parameter (Four LSB bits)
Note: In order to get accurate values the AFC has to be disabled during the read by clearing the en bit in the AFC Control Command
(page 22). The AFC offset value (OFFS bits in the status word) is represented as a two’s complement number. The actual
frequency offset can be calculated as the AFC offset value multiplied by the current PLL frequency step (see the Frequency
Setting Command on page 18).
28
Si4421
INTERRUPT HANDLING
In order to achieve low power consumption there is an advanced event handling circuit implemented. The device has a very low
power consumption mode, so called sleep mode. In this mode only a few parts of the circuit are working. In case of an event, the
device wakes up, switches into active mode and an interrupt signal generated on the nIRQ pin to indicate the changed state to the
microcontroller. The cause of the interrupt can be determined by reading the status word of the device (see Status Read Command,
page 28).
Several interrupt sources are available:
RGIT – TX register empty interrupt: This interrupt generated when the transmit register is empty. Valid only when the el
(enable internal data register) bit is set in the Configuration Setting Command (page 16), and the transmitter is enabled in
the Power Management command.
FFIT – the number of bits in the RX FIFO reached the preprogrammed level: When the number of received data bits in the
receiver FIFO reaches the threshold set by the f3…f0 bits of the FIFO and Reset Mode Command (page 21) an interrupt is
fired. Valid only when the ef (enable FIFO mode) bit is set in the Configuration Setting Command and the receiver is enabled
in the Power Management Command (page 16).
POR – power on reset interrupt: An interrupt generated when the change on the VDD line triggered the internal reset circuit or
a software reset command was issued. For more details, see the Reset Modes section (page 35).
RGUR – TX register under run: The automatic baud rate generator finished the transmission of the byte in the TX register
before the register write occurred. Valid only when the el (enable internal data register) bit is set in the Configuration Setting
Command and the transmitter is enabled in the Power Management command.
FFOV – FIFO overflow: There are more bits received than the capacity of the FIFO (16 bits). Valid only when the ef (enable
FIFO mode) bit is set in the Configuration Setting Command and the receiver is enabled in the Power Management
command
WKUP – wake-up timer interrupt: This interrupt event occurs when the time specified by the Wake-Up Timer Command (page
26) has elapsed. Valid only when the ew bit is set in the Power Management Command.
EXT – external interrupt: Follows the level of the nINT pin if it is configured as an external Interrupt pin in the Receiver Control
Command (page 18, p16 bit is cleared).
LBD – low battery detector interrupt: Occurs when the VDD goes below the programmable low battery detector threshold level
(v3…v0 bits in the Low Battery and Microcontroller Clock Divider Command, page 27). Valid only when the eb (enable low
battery detector) bit is set in the Power Management Command.
If any of the sources becomes active, the nIRQ pin will change to logic low level, and the corresponding bit in the status byte will be
HIGH.
Clearing an interrupt actually implies two things:
Releasing the nIRQ pin to return to logic high
Clearing the corresponding bit in the status byte
This may be completed with the following interrupt sources:
RGIT: both the nIRQ pin and status bit remain active until the register is written (if under-run does not occur until the register
write), or the transmitter and the TX latch are switched off.
FFIT: both the nIRQ pin and status bit remain active until the FIFO is read (a FIFO IT threshold number of bits have been
read), the receiver is switched off, or the RX FIFO is switched off.
POR: both the nIRQ pin and status bit can be cleared by the read status command
RGUR: this bit is always set together with RGIT; both the nIRQ pin and the status bit remain active until the transmitter and
the TX latch is switched off.
FFOV: this bit is always set together with FFIT; it can be cleared by the status read command, but the FFIT bit and hence the
nIRQ pin will remain active until the FIFO is read fully, the receiver is switched off, or the RX FIFO is switched off.
WKUP: both the nIRQ pin and status bit can be cleared by the read status command
EXT: both the nIRQ pin and status bit follow the level of the nINT pin
LBD: the nIRQ pin can be released by the reading the status, but the status bit will remain active while the VDD is below the
threshold.
29
Si4421
The best practice in interrupt handling is to start with a status read when interrupt occurs, and then make a decision based on the
status byte. It is very important to mention that any interrupt can “wake-up” the EZradio chip from sleep mode. This means that the
crystal oscillator starts to supply clock signal to the microcontroller even if the microcontroller has its own clock source. Also, the
Si4421 will not go to low current sleep mode if any interrupt remains active regardless to the state of the ex (enable crystal
oscillator) bit in the Power Management Command (page 16). This way the microcontroller always can have clock signal to process
the interrupt. To prevent high current consumption and this way short battery life, it is strongly advised to process and clear every
interrupt before going to sleep mode. All unnecessary functions should be turned off to avoid unwanted interrupts. Before freezing
the microcontroller code, a thorough testing must be performed in order to make sure that all interrupt sources are handled before
putting the radio device to low power consumption sleep mode. If the dc bit is set in the Power Management Command, then only
the ex bit controls the crystal oscillator (supposing that both the er and et bits are cleared), the interrupts have no effect on it.
TX REGISTER BUFFERED DATA TRANSMISSION
In this operating mode (enabled by bit el, in the Configuration Setting Command, page 16) the TX data is clocked into one of the two
8-bit data registers. The transmitter starts to send out the data from the first register (with the given bit rate) when bit et is set with
the Power Management Command (page 16). The initial value of the data registers (AAh) can be used to generate preamble. During
this mode, the SDO pin can be monitored to check whether the register is ready (SDO is high) to receive the next byte from the
microcontroller.
TX register simplified block diagram (before transmit)
TX register simplified block diagram (during transmit)
30
Si4421
Typical TX register usage
Enabling the Transmitter preloads the TX
latch with 0xAAAA
SPI commands
(nSEL, SCK, SDI)
Do not switch the et off here, because the
TX byte1 is not transmitted out
only stored into the internal register!
Conf. Set.
Power Man
TX latch wr
TX latch wr
Power Man
Conf. Set.
el = 1
et = 1
TX byte1
Dummy
TX byte
et = 0
el = 0
et bit
(enable transmitter)
enable
Synthesizer / PA
Synt.
PA
Ttx_XTAL_ON*
TX data
0xAA
0xAA
TX byte1
Fraction of the
Dummy byte
nIRQ
SDO**
Notes:
*Ttx_XTAL_ON is the start-up time of the PLL + PA with running crystal oscillator
** SDO is tri-state if nSEL is logic high.
Note: The content of the data registers are initialized by clearing bit et.
A complete transmit sequence should be performed as follows:
a.
Enable the TX register by setting the el bit to 1 (Configuration Setting Command, page 16)
b.
The TX register automatically filled out with 0xAAAA, which can be used to generate preamble.
c.
Enable the transmitter by setting the et bit (Power Management Command, page 16)
d.
The synthesizer and the PLL turns on, calibrates itself then the power amplifier automatically enabled
e.
The TX data transmission starts
f.
When the transmission of the byte completed, the nIRQ pin goes high, the SDO pin goes low at the same time. The nIRQ
pulse shows that the first 8 bits (the first byte, by default 0xAA) has transmitted. There are still 8 bits in the transmit
register.
g.
The microcontroller recognizes the interrupt and writes a data byte to the TX register
h.
Repeat f. - g. until the last data byte reached
i.
Using the same method, transmit a dummy byte. The value of this dummy byte can be anything.
j.
The next high to low transition on the nIRQ line (or low to high on the SDO pin) shows that the transmission of the data
bytes ended. The dummy byte is still in the TX latch.
k.
Turn off the transmitter by setting the et bit to 0. This event will probably happen while the dummy byte is being
transmitted. Since the dummy byte contains no useful information, this corruption will cause no problems.
l.
Clearing the el bit clears the Register Underrun interrupt; the nIRQ pin goes high, the SDO low.
It is possible to perform this sequence without sending a dummy byte (step i.) but after loading the last data byte to the transmit
register the PA turn off should be delayed for at least 16 bits time. The clock source of the microcontroller (if the clock is not supplied
by the Si4421) should be stable enough over temperature and voltage to ensure this minimum delay under all operating
circumstances.
When the dummy byte is used, the whole process is driven by interrupts. Changing the TX data rate has no effect on the algorithm
and no accurate delay measurement is needed.
31
Si4421
RX FIFO BUFFERED DATA READ
In this operating mode, incoming data are clocked into a 16-bit FIFO buffer. The receiver starts to fill up the FIFO when the Valid Data
Indicator (VDI) bit and the synchron pattern recognition circuit indicates potentially real incoming data. This prevents the FIFO from
being filled with noise and overloading the external microcontroller.
Interrupt Controlled Mode:
The user can define the FIFO IT level (the number of received bits) which will generate the nFFIT when exceeded. The status bits
report the changed FIFO status in this case.
Polling Mode:
When nFFS signal is low the FIFO output is connected directly to the SDO pin and its content can be clocked out by the SCK. Set the
FIFO IT level to 1. In this case, as long as FFIT indicates received bits in the FIFO, the controller may continue to take the bits away.
When FFIT goes low, no more bits need to be taken.
An SPI read command is also available to read out the content of the FIFO (Receiver FIFO Read Command, page 22).
FIFO Read Example with FFIT Polling
nSEL
0
1
2
3
4
SCK
nFFS
FIFO read out
SDO
FIFO OUT
FO+1
FO+2
FO+3
FO+4
FFIT
Note: During FIFO access fSCK cannot be higher than fref /4, where fref is the crystal oscillator frequency. When the duty-cycle of the
clock signal is not 50% the shorter period of the clock pulse should be at least 2/fref .
RECOMMENDED PACKET STRUCTURES
Preamble
Synchron word
(Can be network ID)
Payload
CRC
Minimum length
4 - 8 bits (1010b or 0101b)
D4h (programmable)
?
4 bit - 1 byte
Recommended length
8 -12 bits (e.g. AAh or 55h)
2DD4h (D4 is programmable)
?
2 byte
32
Si4421
CRYSTAL SELECTION GUIDELINES
The crystal oscillator of the Si4421 requires a 10 MHz parallel mode crystal. The circuit contains an integrated load capacitor in
order to minimize the external component count. The internal load capacitance value is programmable from 8.5 pF to 16 pF in 0.5
pF steps. With appropriate PCB layout, the total load capacitance value can be 10 pF to 20 pF so a variety of crystal types can be
used.
When the total load capacitance is not more than 20 pF and a worst case 7 pF shunt capacitance (C0) value is expected for the
crystal, the oscillator is able to start up with any crystal having less than 100 ohms ESR (equivalent series loss resistance). However,
lower C0 and ESR values guarantee faster oscillator startup.
The crystal frequency is used as the reference of the PLL, which generates the local oscillator frequency (fLO). Therefore, fLO is directly
proportional to the crystal frequency. The accuracy requirements for production tolerance, temperature drift and aging can thus be
determined from the maximum allowable local oscillator frequency error.
Whenever a low frequency error is essential for the application, it is possible to “pull” the crystal to the accurate frequency by
changing the load capacitor value. The widest pulling range can be achieved if the nominal required load capacitance of the crystal is
in the “midrange”, for example 16 pF. The “pull-ability” of the crystal is defined by its motional capacitance and C0.
Maximum XTAL Tolerances Including Temperature and Aging [ppm]
Bit Rate: 2.4 kbps
Deviation [± kHz]
30
45
60
75
90
105
120
433 MHz
20
30
50
70
90
100
100
868 MHz
10
20
25
30
40
50
60
915 MHz
10
15
25
30
40
50
50
30
45
60
75
90
105
120
433 MHz
15
30
50
70
80
100
100
868 MHz
8
15
25
30
40
50
60
915 MHz
8
15
25
30
40
50
50
30
45
60
75
90
105
120
433 MHz
don't use
5
20
30
50
75
75
868 MHz
don't use
3
10
20
25
30
40
915 MHz
don't use
3
10
15
25
30
40
Bit Rate: 9.6 kbps
Deviation [± kHz]
Bit Rate: 38.4 kbps
Deviation [± kHz]
Bit Rate: 115.2 kbps
Deviation [± kHz]
105
120
135
150
165
180
195
433 MHz
don't use
3
20
30
50
70
80
868 MHz
don't use
don't use
10
20
25
35
45
915 MHz
don't use
don't use
10
15
25
30
40
33
Si4421
RX-TX ALIGNMENT PROCEDURES
RX-TX frequency offset can be caused only by the differences in the actual reference frequency. To minimize these errors it is
suggested to use the same crystal type and the same PCB layout for the crystal placement on the RX and TX PCBs.
To verify the possible RX-TX offset it is suggested to measure the CLK output of both chips with a high level of accuracy. Do not
measure the output at the XTL pin since the measurement process itself will change the reference frequency. Since the carrier
frequencies are derived from the reference frequency, having identical reference frequencies and nominal frequency settings at the
TX and RX side there should be no offset if the CLK signals have identical frequencies.
It is possible to monitor the actual RX-TX offset using the AFC status report included in the status byte of the receiver. By reading out
the status byte from the receiver, the actual measured offset frequency will be reported. In order to get accurate values the AFC has
to be disabled during the read by clearing the en bit in the AFC Control Command (page 22).
34
Si4421
RESET MODES
The chip will enter into reset mode if any of the following conditions are met:
Power-on reset: During a power up sequence until the Vdd has reached the correct level and stabilized
Power glitch reset: Transients present on the Vdd line
Software reset: Special control command received by the chip
Power-on reset
After power up the supply voltage starts to rise from 0V. The reset block has an internal ramping voltage reference (reset-ramp
signal), which is rising at 100mV/ms (typical) rate. The chip remains in reset state while the voltage difference between the actual
Vdd and the internal reset-ramp signal is higher than the reset threshold voltage, which is 600 mV (typical). As long as the Vdd voltage
is less than 1.6V (typical) the chip stays in reset mode regardless the voltage difference between the Vdd and the internal ramp
signal.
The reset event can last up to 100ms supposing that the Vdd reaches 90% its final value within 1ms. During this period, the chip
does not accept control commands via the serial control interface.
Power-on reset example:
Power glitch reset
The internal reset block has two basic mode of operation: normal and sensitive reset. The default mode is sensitive, which can be
changed by the appropriate control command (see Related control commands at the end of this section). In normal mode the power
glitch detection circuit is disabled.
There can be spikes or glitches on the Vdd line if the supply filtering is not satisfactory or the internal resistance of the power supply is
too high. In such cases if the sensitive reset is enabled an (unwanted) reset will be generated if the positive going edge of the Vdd has
a rising rate greater than 100mV/ms and the voltage difference between the internal ramp signal and the Vdd reaches the reset
threshold voltage (600 mV). Typical case when the battery is weak and due to its increased internal resistance a sudden decrease of
the current consumption (for example turning off the power amplifier) might lead to an increase in supply voltage. If for some reason
the sensitive reset cannot be disabled step-by-step decrease of the current consumption (by turning off the different stages one by
one) can help to avoid this problem.
Any negative change in the supply voltage will not cause reset event unless the Vdd level reaches the reset threshold voltage (250mV
in normal mode, 1.6V in sensitive reset mode).
If the sensitive mode is disabled and the power supply turned off the Vdd must drop below 250mV in order to trigger a power-on reset
event when the supply voltage is turned back on. If the decoupling capacitors keep their charges for a long time it could happen that
no reset will be generated upon power-up because the power glitch detector circuit is disabled.
Note that the reset event reinitializes the internal registers, so the sensitive mode will be enabled again.
35
Si4421
Sensitive Reset Enabled, Ripple on Vdd:
Vdd
Reset threshold voltage
(600mV)
Reset ramp line
(100mV/ms)
1.6V
time
nRes
output
H
L
Sensitive reset disabled:
Vdd
Reset threshold voltage
(600mV)
Reset ramp line
(100mV/ms)
250mV
time
nRes
output
H
L
Software reset
Software reset can be issued by sending the appropriate control command (described at the end of the section) to the chip. The
result of the command is the same as if power-on reset was occurred but the length of the reset event is much less, 0.25ms typical.
The software reset works only when the sensitive reset mode is selected.
Vdd line filtering
During the reset event (caused by power-on, fast positive spike on the supply line or software reset command), it is very important to
keep the Vdd line as smooth as possible. Noise or periodic disturbing signal superimposed the supply voltage may prevent the part
getting out from reset state. To avoid this phenomenon use adequate filtering on the power supply line to keep the level of the
disturbing signal below 100mVp-p in the DC – 50kHz range for 200ms from Vdd ramp start.. Typical example when a switch-mode
regulator is used to supply the radio, switching noise may be present on the Vdd line. Follow the manufacturer’s recommendations
how to decrease the ripple of the regulator IC and/or how to shift the switching frequency.
Related control commands
FIFO and Reset Mode Command (page 21)
Setting bit to high will change the reset mode to normal from the default sensitive.
SW Reset Command
Issuing FE00h command will trigger software reset (sensitive reset mode must be enabled). See the Wake-up Timer
Command (page 26).
36
Si4421
TYPICAL PERFORMANCE CHARACTERISTICS
Channel Selectivity and Blocking:
90
80
70
60
50
40
30
20
434 MHz
868 MHz
10
ETSI
0
0
1
2
3
4
5
6
7
8
9
10
11
12
CW interferer offset from carrier [MHz]
Note:
LNA gain maximum, filter bandwidth 67 kHz, data rate 9.6 kbps, AFC switched off, FSK deviation ± 45 kHz, Vdd = 2.7 V
Measured according to the descriptions in the ETSI Standard EN 300 220-1 v2.1.1 (2006-01 Final Draft), section 9
The ETSI limit given in the figure is drawn by taking -106dBm at 9.6kbps typical sensitivity into account, and corresponds to
receiver class 2 requirements (section 4.1.1)
Phase Noise Performance in the 433, 868 and 915 MHz Bands:
433 MHz
868 MHz
915 MHz
(Measured under typical conditions: Top = 27 oC; Vdd = Voc = 2.7 V)
37
Si4421
BER Curves in 433 MHz Band:
1
10-1
1.2k
2.4k
10-2
4.8k
9.6k
19.2k
38.4k
10-3
10-4
10-5
10-6
-120
57.6k
115.2k
-115
-110
-105
-100
-95
-90
BER Curves in 868 MHz Band:
1
1.2k
10-1
10-4
2.4k
4.8k
9.6k
19.2k
38.4k
10-5
57.6k
115.2k
10-2
10-3
10-6
-115
-110
-105
-100
-95
-90
-85
The table below shows the optimal receiver baseband bandwidth (BW) and transmitter deviation frequency (δfFSK) settings for
different data-rates supposing no transmit receive offset frequency. If TX/RX offset (for example due to crystal tolerances) have to be
taken into account, increase the BW accordingly.
1.2 kbps
2.4 kbps
4.8 kbps
9.6 kbps
19.2 kbps
38.4 kbps
57.6 kbps
115.2 kbps
BW=67 kHz
fFSK =45 kHz
BW=67 kHz
fFSK =45 kHz
BW=67 kHz
fFSK =45kHz
BW=67 kHz
fFSK =45 kHz
BW=67 kHz
fFSK =45 kHz
BW=134 kHz
fFSK =90 kHz
BW=134 kHz
fFSK =90 kHz
BW=200 kHz
fFSK =120 kHz
38
Si4421
Receiver Sensitivity over Ambient Temperature (433 MHz, 2.4 kbps, fFSK: 45 kHz, BW: 67 kHz):
434 MHz
-100
-103
-106
dBm
2.2V
2.7V
3.3V
-109
3.8V
-112
-115
-50
-25
0
25
50
75
100
Celsius
Receiver Sensitivity over Ambient Temperature (868 MHz, 2.4 kbps, fFSK: 45 kHz, BW: 67 kHz):
868 MHz
-100
-103
-106
dBm
2.2V
2.7V
3.3V
-109
3.8V
-112
-115
-50
-25
0
25
50
75
100
Celsius
39
Si4421
REFERENCE DESIGNS
Evaluation Board with 50 Ohm Matching Network
3
SDO
4
IRQ
5
DATA
6
DCLK
7
8
C3
*
C2
C1
10nF
2.2uF
ARSSI
NSEL
VDD
SDO
RF1
NIRQ
RF2
FSK/DATA/NFFS
VSS
DCLK/CFIL/FFIT NRES
CLK
XTL/REF
IA4421
CLK_OUT
TP61
VDD
GND
SCK
15
ARSSI
14
GND
*
GND
C10 *
13
*
L2
SEL
NINT/VDI
SDI
12
11
10
*
RESET
GND
*
GND
*
C9
9
C11
*
CN62
optional
ANT
GND
*
L3
2
C8
MATCHING_NETWORK
VDI
VDD
SCK
GND
16
GND
SCK
IRQ
ARSSI
VDI
RESET
1
Q61
DATA
SEL
SDO
SDI
L4
IC1
DCLK
SDI
VDD
1
2
3
4
5
6
7
8
9
10
11
12
13
14
10MHz
CN61
L1
C4
T P62
4.7nF
ARSSI
Schematics
GND
* See values in the table
VDD
VDD
GND
Frequency Dependent Component Values
f [MHz]
434
L1 [nH]
L2 [nH]
18
L3 [nH]
L4 [nH]
C8 [pF]
18
C9 [pF]
C10 [pF]
C11 [pF]
C3 [pF]
47
390
5
2.7
2.7
220
220
868
3.9
18
100
3.9
2.7
1.2
1.8
47
47
915
3.6
16
100
3.6
2.7
1.2
1.8
33
33
Recommended Component Types
Component
Manufacturer
L1
L4
Part number
Note
434MHz
868 MHz
915MHz
Coilcraft
0603CS-18NX
0603CS-3N9X
0603CS-3N9X
Coilcraft
0603CS-18NX
0603CS-3N9X
0603CS-3N9X
1
L2
Coilcraft
0603CS-47NX
0603CS-18NX
0603CS-16NX
1
1
L3
Coilcraft
0603CS-R39X
0603CS-R10X
0603CS-R10X
2
C9
Murata
GRM1885C1H2R7CZ01B
GRM1885C1H1R2CZ01B
GRM1885C1H1R2CZ01B
3
C8
Murata
GRM1885C1H5R0CZ01B
GRM1885C1H2R7CZ01B
GRM1885C1H2R7CZ01B
3
C10
Murata
GRM1885C1H2R7CZ01B
GRM1885C1H1R8CZ01B
GRM1885C1H1R8CZ01B
3, 4
C11
Murata
GRM1885C1H221JA01B
GRM1885C1H470JZ01B
GRM1885C1H330JZ01B
3
C3
Murata
GRM1885C1H221JA01B
GRM1885C1H470JZ01B
GRM1885C1H330JZ01B
3
For component selection guidelines, see the notes on the next page.
40
Si4421
Notes:
1. SRF, DCR and Q should be similar if components from other manufacturer used
2. The SRF should be twice as much as the operation frequency
3. The dielectric type should be C0G and the resonant frequency should be similar if components from alternative vendor used.
4. The values are valid for 1.5mm thick FR4 PCB. If thinner board used the capacitor value should be increased (and vice versa)
to minimize the level of the second harmonic components.
PCB Layout
Top View
Bottom View
41
Si4421
Evaluation Board with Resonant PCB Antenna (BIFA)
CLKIN
DATA
DCLK
R8 10k
DATA
DCLK
SCK
2
SEL
3
IRQ
SDO
C3
*
SDO
4
C2
C1
IRQ
5
10nF
2.2uF
DATA
6
GND
DCLK
R5
DTO
10k
7
8
C6
100pF
TP3
TP1
CON40-0
GND
SDI
SCK
GND
NINT/VDI
ARSSI
NSEL
VDD
SDO
RF1
NIRQ
RF2
FSK/DATA/NFFS VSS
DCLK/CFIL
CLK
NRES
XTL/REF
16
VDI
15
ARSSI
VDD
SDI
1
14
13
*
L1
12
11
10
9
RESET
* See values in the table
IA4421
CLKIN 1
JP1
2
3
Q1
GND
10MHz
R7 100k
IC1
DTO
VDI
RESET
CLK_OUT
VDI
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
VDD
R6 10k
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
GND
CS1
SDI
SCK
SEL
DATA
10nF
ARSSI
C4
SDO
IRQ
FFE
VDI
FFS/DATA
SEL
SCK
SDI
Schematics
GND
Note: Components R5 to R8 and C6 are needed for connection to the ISM Chipset Development Kit load board (IA ISM-DK3) and are
not necessary in an application.
Frequency Dependent Component Values
Band
C3 [pF]
L1 [nH]
868 MHz
47
22
Dual (868/915 MHz)
47/33
18
915 MHz
33
15
42
Si4421
PCB Layout (Antenna designed for 868/915 MHz band)
Top View
Bottom View
43
Si4421
PACKAGE INFORMATION
16-pin TSSOP
See Detail “A”
Section B-B
Gauge Plane
0.25
Detail “A””
Symbol
A
A1
A2
b
b1
c
c1
D
e
E
E1
L
L1
R
R1
1
2
3
Min.
0,05
0,80
0,19
0,19
0,09
0,09
4,90
4,30
0,50
Dimensions in mm
Nom.
Max.
1,20
0,15
0,90
1,05
0,30
0,22
0,25
0,20
0,16
5,00
5,10
0.65 BSC.
6.40 BSC.
4,40
4,50
0,60
0,75
1.00 REF.
0,09
0,09
0
8
12 REF.
12 REF.
Dimensions in Inches
Nom.
Max.
0,047
0,002
0,006
0,031
0,035
0,041
0,007
0,012
0,007
0,009
0,010
0,004
0,008
0,004
0,006
0,193
0,197
0,201
0.026 BSC.
0.252 BSC.
0,169
0,173
0,177
0,020
0,024
0,030
0.39 REF.
0,004
0,004
0
8
12 REF.
12 REF.
Min.
44
Si4421
RELATED PRODUCTS AND DOCUMENTS
Si4421 Universal ISM Band FSK Transceiver
DESCRIPTION
ORDERING NUMBER
Si4421 16-pin TSSOP
Si4421-IC CC16
Revision # A1
Demo Boards and Development Kits
DESCRIPTION
ORDERING NUMBER
Development Kit
IA ISM – DK
ISM Repeater Demo
IA ISM – DARP
Related Resources
DESCRIPTION
ORDERING NUMBER
Antenna Selection Guide
IA ISM – AN1
Antenna Development Guide
IA ISM – AN2
Si4221 Universal ISM Band FSK Transmitter
See www.silabs.com for details
Si4320 Universal ISM Band FSK Receiver
See www.silabs.com for details
Note: Volume orders must include chip revision to be accepted.
IAI provides technical support ONLY through its on-line support system: http://www.silabs.com/integration/d_Technical.php. Please
contact our support team by filling out the online query submission, a representative will reply within 2-3 working days.
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Tel: 512.416.8500
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The specifications and descriptions in this document are based on
information available at the time of publication and are subject to change
without notice. Silicon Laboratories assumes no responsibility for errors or
omissions, and disclaims responsibility for any consequences resulting from
the use of information included herein. Additionally, Silicon Laboratories
assumes no responsibility for the functioning of undescribed features or
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Silicon Labs intends to provide customers with the latest, accurate, and in-depth documentation of all peripherals and modules available for system and software implementers using or
intending to use the Silicon Labs products. Characterization data, available modules and peripherals, memory sizes and memory addresses refer to each specific device, and "Typical"
parameters provided can and do vary in different applications. Application examples described herein are for illustrative purposes only. Silicon Labs reserves the right to make changes without
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