SEMTECH SX1223I073TRT

SX1223
SX1223
425 – 475 MHz / 850 – 950 MHz
Integrated UHF Transmitter
GENERAL DESCRIPTION
KEY PRODUCT FEATURES
The SX1223 is a single chip transmitter operating in
UHF frequency bands including the 434, 869 and 915
MHz license-free ISM (Industrial Scientific and
Medical) bands. Its highly integrated architecture
allows for minimum external components while
maintaining design flexibility. All major RF
communication parameters are programmable and
most of them can be set dynamically. The SX1223
offers the advantage of high data rate communication
at rates of up to 153.6 kbit/s. The SX1223 is
optimized for low cost applications while offering high
RF output power. The device is suitable for
applications which have to satisfy either the European
(ETSI-300-220) or the North American (FCC part 15)
regulatory standards.
•
•
APPLICATIONS
•
•
•
Automated Meter Reading (AMR)
Home Automation and Access Control
High-Quality Speech, Music and Data over RF
Rev 5 May 2007
•
•
•
•
•
RF output power: up to +10 dBm
Low power consumption:
TX = 25.8 mA @ 10 dBm (typical)
Supply voltage down to 2.0 V
Data rate from 1.2 to 153.6 kbit/s
On-chip frequency synthesizer
Continuous phase 2-level FSK modulation
Very small RoHS green package (TQFN24, 4mm
x 4mm)
ORDERING INFORMATION
Part number
Temperature
range
SX1223I073TRT(1)
-40 °C to +85 °C
(1)
Package
TQFN24
TR refers to tape & reel.
T refers to Lead Free package.
This device is WEEE and RoHS compliant.
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SX1223
Table of Contents
1
2
3
3.1
3.2
3.2.1
3.2.2
4
4.1
4.1.1
4.1.2
4.1.3
4.1.4
4.1.5
4.1.6
4.2
4.2.1
4.2.2
4.2.3
4.2.4
4.2.5
4.2.6
4.2.7
4.2.8
4.3
4.4
5
5.1
5.2
5.2.1
5.2.2
5.2.3
6
6.1
6.2
6.3
6.4
6.5
7
Functional Block Diagram .................................................................................................................. 3
Pin description..................................................................................................................................... 4
Electrical Characteristics.................................................................................................................... 5
Absolute Maximum Operating Ranges.................................................................................................. 5
Specifications ........................................................................................................................................ 5
Operating Range ................................................................................................................................... 5
Electrical Specifications......................................................................................................................... 5
General description............................................................................................................................. 7
Frequency synthesizer........................................................................................................................... 7
General Structure .................................................................................................................................. 7
Crystal Oscillator ................................................................................................................................... 8
VCO....................................................................................................................................................... 8
Charge Pump ...................................................................................................................................... 10
Loop Filter............................................................................................................................................ 10
Lock Detect.......................................................................................................................................... 11
Modulator............................................................................................................................................. 11
Introduction.......................................................................................................................................... 11
Data Interface ...................................................................................................................................... 11
Bit Rate Setting for MW1 and MW2 .................................................................................................... 12
Deviation Setting for MW1 and MW2 .................................................................................................. 12
Shaping for MW1 and MW2 ................................................................................................................ 13
Modulator Saturation for MW1 and MW2............................................................................................ 13
Summary of Modulator Settings for MW1 and MW2........................................................................... 13
Frequency deviation setting for MW3.................................................................................................. 13
Power Amplifier ................................................................................................................................... 14
Voltage regulators ............................................................................................................................... 14
Serial Interface definition and Principles of operation .................................................................. 15
Serial Control Interface........................................................................................................................ 15
Configuration and Status registers ...................................................................................................... 16
Operating Modes ................................................................................................................................. 16
Other Settings...................................................................................................................................... 17
Optional and Test Parameters ............................................................................................................ 19
Application Information .................................................................................................................... 21
Matching network of the transmitter .................................................................................................... 21
Reference crystal for the frequency synthesizer ................................................................................. 22
Loop filter components ........................................................................................................................ 22
Recommended modulation conditions ................................................................................................ 22
TYPICAL APPLICATION SCHEMATICS ............................................................................................ 23
Packaging information...................................................................................................................... 24
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SX1223
The SX1223 is a single chip transmitter operating in the 433, 868 and 915MHz license free ISM (Industrial Scientific
and Medical) frequency bands; the frequency range is selectable between 425-475 MHz and 850-950 MHz. The
modulation scheme is 2-FSK. The circuit has 4 functional modes: sleep mode, where all the blocks are switched off,
standby mode, where only the crystal oscillator is on, synthesizer mode, where the frequency synthesizer is running,
and transmission mode, where all the blocks are on, including the power amplifier. It complies with European (ETSI
EN 300-220-1) and North American (FCC part 15) regulations.
There are three different methods of modulation:
- (mw1) pulling the VCO in closed loop: all the specified bit rates can be implemented, but a DC-free coding
scheme is needed (e.g. Manchester), which means that the real information rate is half the bit rate,
- (mw2) pulling the VCO in open loop: all the specified bit rates can be implemented, and NRZ coding is
allowed; but, since the control voltage of the VCO will drift due to leakage currents, the duration of the
transmission is limited,
- (mw3) switching between two frequency divider ratios in closed loop; bit rates from 1.2 to 19.2 kbit/s are
achievable with this method.
The circuit works on two selectable supply voltage ranges:
- (sv1) the high range (2.2 V to 3.6 V), where the on-chip regulators are activated,
- (sv2) the low range (2.0 V to 2.5 V), where the on-chip regulators are off.
A 3-wire bi-directional bus is used to communicate with SX1223 and gives access to the configuration register. An
output clock of 1 MHz is user selectable for driving an external micro-controller.
SX1223 comes in a RoHS green TQFN-24 package (body size: 4 mm x 4 mm).
FUNCTIONAL BLOCK DIAGRAM
CRYSTAL
XTA
VDDF
LOOP FILTER
XTB
LD
OSCILLATOR
CPOUT
VARIN
LOCK
DETECT
SO
VDD
LDO
÷
CLOCK
GEN
M
PFD
PFD
LDO
Open Loop
OPAMP
÷ N,A
N,A
VDDP
÷ 22
RFOUT
PA
VCO
VCO
÷ 22
MOD
BIAS
DATA & CONTROL INTERFACE
1
SI
EN
SCK
DATAIN
DCLK
CLKOUT
LDO
SX1223
VDDD
VDD
Figure 1: SX1223 block diagram
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SX1223
2
PIN DESCRIPTION
Pin
Name
I/O
Function
1
VDD
-
Main analog power supply
Max 3.6V in sv1-mode
Max 2.5V in sv2-mode
2
VSSP
-
PA ground
3
VDDP
-
4
RFOUT
OUT
RF output
5
VSSP
-
PA ground
6
PTATBIAS/PAC
IN/OUT
PTAT source bias resistor / PA start-up control capacitor
7
XTB
IN/OUT
Crystal oscillator pin & input for external reference
8
XTA
IN/OUT
Crystal oscillator pin
9
VDDD
-
In sv1-mode: Digital LDO output, capacitor needed
In sv2-mode: Digital power supply, max 2.5V
10
VSSD
-
Digital ground
11
VDD
-
Main digital power supply
Max 3.6V in sv1-mode
Max 2.5V in sv2-mode
12
LD
OUT
Lock detect output
13
CLKOUT
OUT
Output clock (1 MHz)
14
DCLK
OUT
Data clock output
15
DATAIN
IN
Data input
16
SCK
IN
3-wire interface clock input
17
EN
IN
Enable signal for the 3-wire interface
18
SI
IN
3-wire interface data input
19
SO
OUT
3-wire interface data output
20
CPOUT
OUT
PLL charge pump output
21
VARIN
IN
VCO varactor input
22
VSSF
-
Analog ground
23
VDDF
-
In sv1-mode: Analog LDO output, capacitor needed
In sv2-mode: Analog power supply max 2.5 V
24
CIBIAS
OUT
CI source bias resistor
In sv1-mode: PA LDO output, capacitor needed
In sv2-mode: PA power supply, max 2.5 V
Note: Thermal Pad on the bottom of the package must be connected to ground.
Thermal
Pad
24
bottom view
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SX1223
3
ELECTRICAL CHARACTERISTICS
3.1
ABSOLUTE MAXIMUM OPERATING RANGES
Stresses above the values listed below may cause permanent device failure. Exposure to absolute maximum
ratings for extended periods may affect device reliability.
Symbol
Description
Min.
Max.
Unit
VDDmax
Supply voltage
-0.4
3.9
V
Tmax
Storage temperature
-55
125
°C
Min.
Max.
Unit
V
The device is ESD sensitive and should be handled with precaution.
3.2
SPECIFICATIONS
3.2.1
Operating Range
Symbol
Description
VDD
Supply voltage (*)
2.0
3.6
T
Temperature
-40
85
°C
CLop
Load capacitance on digital ports
-
25
pF
(*) Divided in two ranges:
- (sv1) high range, 2.2 V – 3.6 V, using on-chip regulators,
- (sv2) low range, 2.0 V – 2.5 V, without using the regulators.
3.2.2
Electrical Specifications
The table below gives the electrical specifications of the transmitter under the following conditions:
Supply Voltage = 3.3 V, temperature = 25 °C, 2-leve l FSK, fc = 915 MHz, Output power = 10 dBm, Bit rate = 38.4
kb/s, ∆f = 100 kHz, XTAL = 16 MHz, modulation by pulling the VCO in open loop (mw2), and conditions as defined
in section 6, unless otherwise specified.
Symbol
Description
Conditions
Min
Typ
Max
Unit
-
0.3
1
µA
IDDSL
Supply current in sleep
mode
IDDST
Supply current in standby
mode
Crystal oscillator running,
CLKOUT off
-
0.2
0.3
mA
IDDFS
Supply current in FS mode
Frequency synthesizer
running
-
5
6
mA
IDDT
Supply current during
transmission
-
25.8
-
mA
FR
Frequency range
10 dBm
0dBm
-
14
-
mA
425
-
475
MHz
850
-
950
MHz
FDA
Frequency deviation
For FR from 850 to 950 MHz
5
-
255
kHz
FDA_L
Frequency deviation
For FR from 425 to 475 MHz
5
-
200
kHz
∆FDA
Variation of frequency
deviation
- 15
-
+ 15
%
BR
Bit rate
Modulation modes mw1 mw2
1.2
-
153.6
kbit/s
BR_3
Bit rate for mw3 mode
Modulation mode mw3
1.2
-
19.2
kbit/s
SPICLK
SPI clock frequency (SCK)
SCK duty cycle 50% +/-10%
1
MHz
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SX1223
Symbol
Description
Conditions
Min
Typ
Max
Unit
HRFOP
Highest RF output power
Highest programmable output
power
8
10
-
dBm
SRFOP
RF output power steps
RF output power step size
-
3
-
dB
-
-
40
MHz
(8 steps available)
XTAL
Crystal oscillator frequency
TS_OS
Oscillator wake-up time
From sleep mode
-
0.8
2
ms
TS_OS_QS
Oscillator wake-up time in
quick start-up mode
Quick start-up mode
-
0.15
-
ms
Frequency synthesizer
wake-up time
From standby mode (oscillator
running)
-
-
2
ms
-
-
500
µs
TS_FS
Recommended value: 16 MHz
IDDST_QS_typ=0.9mA
(XCO_quick_start,
XCO_high_I = 10)
frequency at most 5 kHz away
from the target
TS_TR
Transmitter wake-up time
From FS mode (frequency
synthesizer running)
TD_TX
Transmission duration in
mw2 mode
Duration during which the
output signal is a proper FSK
signal and the carrier
frequency doesn’t drift by
more than 50 kHz from the
time when the transmitter has
reached its steady-state
(including PA)
30
-
-
ms
TD_TXW
Transmission duration in
mw2 mode
Same conditions as TD_TX,
but over the whole
temperature range
15
-
-
ms
ACP
Power transmitted in the
150 kHz adjacent channel
At 10 dBm output power,
modulated signal
Measured on a 150 kHz
bandwidth centered at 150
kHz from the carrier, ∆f = 40
kHz
-
-16
ACP_mw3
Power transmitted in the
250 kHz adjacent channel
in mw3 modulation mode
At 10 dBm output power,
modulated signal
Measured on a 250 kHz
bandwidth centered at 250
kHz from the carrier, ∆f = 60
kHz
-
-23
-17
dBm
PHN
Phase noise of the output
signal
At 10 dBm output power,
unmodulated signal
Measured at 50 kHz from the
carrier in mw3 mode
-
-83
-80
dBc/Hz
CLKOUT
Output clock
On pin CLKOUT
-
1
-
MHz
VIH
Digital input level high
% VDD
75
-
-
%
VIL
Digital input level low
% VDD
-
-
25
%
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dBm
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SX1223
4
GENERAL DESCRIPTION
The SX1223 is a 2-level FSK transmitter. The circuit operates in one of two frequency ranges, 425 to 475 MHz, and
850 to 950 MHz, allowing the 3 main ISM frequency bands (434 MHz, 869 MHz and 915 MHz) to be addressed by
the circuit. It is capable of operating at data rates between 1.2 and 153.6 kbit/s, making it ideally suited for
applications where high data rates are required.
The SX1223 is a highly programmable device – channel, bit rate, frequency deviation and output power – which
makes it extremely flexible to meet a large number of end user requirements.
The main functional blocks of the SX1223 are the frequency synthesizer, the modulator, the power amplifier (PA),
the voltage regulators and some additional service blocks. The device also includes a set of configuration registers
and a digital interface. In a typical application, the SX1223 is programmed by a microcontroller via the 3-wire serial
bus SI, SO, SCK to write to and read from the internal registers.
The Frequency Synthesizer generates the carrier (the local oscillator (LO) signal).
The Modulator performs the modulation of the carrier by the input bit stream.
The Power Amplifier amplifies the modulated RF signal to the antenna port.
The Voltage Regulators generate regulated supply voltages for the different parts of the chip, and allow battery
voltages up to 3.6 V to be used.
The Service Blocks provide the internal voltage and current sources and provide all the necessary functions for the
circuit to work properly.
The Configuration Registers are a set of registers that are used to store various settings to operate the SX1223
transmitter circuit. Please refer to Section 5.2 for the detailed descriptions of these registers. These registers are
accessed in write or read mode through the 3-wire serial bus, as described in Section 5.1.
The Digital Interface provides internal control signals for the whole circuit according to the configuration register
settings.
4.1
FREQUENCY SYNTHESIZER
4.1.1 General Structure
The frequency synthesizer is an integer-N PLL and consists of a voltage-controlled oscillator (VCO), a crystal
oscillator, a prescaler, programmable frequency dividers and a phase-detector. The loop-filter is external for
flexibility and can be a simple passive circuit. The lengths of the M and N and A counters are respectively 12, 12
and 6 bits.
To enable the prescaler Prescal_s register (address 16, bit 4) has to be written to 1. The M, N and A values can be
calculated from the formula:
f RF =
where
fXCO:
fRF:
FreqBand:
f XCO
(16 ⋅ N + A)
M ⋅ ( 2 − FreqBand )
Crystal oscillator frequency
RF frequency
0: RF frequency 425-475 MHz
1: RF frequency 850-950 MHz
M is the divide factor applied to the reference frequency, N and A are the counters of the frequency divider in the
feedback loop of the PLL.
There are two sets of each of these divide factors (M0, N0, A0 and M1, N1, A1). In modulation modes mw1 and
mw2 (register bit Modulation1=0), only the M0, N0 and A0 are used to fix the carrier frequency. If modulation by
using the dividers is selected (mw3, Modulation1=1, Modulation0=0), the two sets are used to program the two RF
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SX1223
frequencies corresponding to the transmission of the two possible values ‘0’ and ‘1’; these frequencies are then
separated by twice the specified single sided frequency deviation ∆f.
4.1.2 Crystal Oscillator
The crystal oscillator (XCO) provides the PLL with the reference signal. The schematic of the crystal oscillator's
external components for 16 MHz is shown in Figure 2.
XTB, pin 7
XTA, pin 8
5p6
5p6
Figure 2: External crystal oscillator circuit with additional (optional) external capacitances
The crystal should be connected between pins XTA and XTB (pin 8 and 7). Either internal or external loading
capacitors for the crystal can be used. Internal capacitors can be enabled by setting the XCOcap_en bit to 1. Faster
start-up time is expected when using external capacitors. The total capacitance when XCOcap_en=1 (and no
external capacitors) is 9 pF. Using a crystal with a load capacitance of 9 pF will give the expected oscillation
frequency.
If XCOcap_en=0, the loading capacitors can be calculated by the following formula:
CL =
1
1
1
+
C1 C2
+ C parasitic
The parasitic capacitance is the pin input capacitance and PCB stray capacitance. For instance, for a 9pF load
crystal and a total parasitic capacitance of 6 pF the recommended values of the external load capacitors are 5.6 pF.
If an external reference is going to be used instead of a crystal, the signal shall be applied to pin 7, XTB. Due to
internal biasing, AC coupling is recommended for use between the external reference and the XTB pin.
The start-up time of the crystal oscillator can vary from 150us to 800us depending on the settings shown in Table
15. Therefore, to save current consumption, the XCO should be turned on before any other circuit block. During
start-up the XCO amplitude will eventually reach a sufficient level to trigger the M-counter. After counting 2 Mcounter output pulses the rest of the circuit is enabled.
Two bits are available to speed up the crystal oscillator start-up: XCO_high_I increases the bias current and
XCO_quick_start boosts this current but only at the start; the first output pulse from the M-divider turns this boost
current off. Typical values for XCO start-up time and current consumption are tablulated below:
XCO_quick_start, XCO_high_I
IDDST [uA]
TS_OS [us]
00
200
800
01
250
750
10
900
200
11
950
150
Table 1: Oscillator start-up time
A reference clock can be generated by SX1223 for use by an external microcontroller. The ClkOut_en configuration
bit determines the status of the CLKOUT pin. When set high CLKOUT is enabled, otherwise it’s disabled. When
enabled, the output frequency at CLKOUT is the crystal oscillator frequency divided by 16, and is then 1 MHz for a
crystal at 16 MHz. This clock signal is disabled in Sleep Mode. When disabled, the CLKOUT pin is set to ground.
4.1.3 VCO
The VCO is fully integrated and has no external components. It oscillates at 1.8 GHz and is divided by 2 or 4 in the
900 MHz or the 450 MHz band respectively (FreqBand = 1 or 0). Additionally two bits in the configuration registers
set the VCO frequency and three bits control the bias current. The two VCO_freq bits have to be programmed by
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SX1223
the user according to the selected frequency band, whereas the three VCO_IB bits can be either forced by the user
or set automatically by the circuit which will select the combination having the best phase noise. This automatic
setting can be enabled by setting the three VCO_IB bits to ‘0’.
Table 2 lists the bias setting used for the different VCO_freq settings in automatic mode. When any of the VCO_IB
bit is set to 1, it will overrule the automatic setting.
RF frequency
425/850 MHz
434/868 MHz
457/915 MHz
475/950 MHz
VCO_IB2
1
1
0
0
VCO_IB1
1
0
1
0
VCO_IB0 VCO_freq1 VCO_freq0
1
0
0
1
0
1
1
1
0
0
1
1
Table 2: VCO bit settings.
The bias bits optimize the phase noise, and the frequency bits control a capacitor bank in the VCO. The tuning
range, the RF frequency versus varactor voltage, is dependent on the VCO frequency setting, and is shown in
Figure 3. When the tuning voltage is in the range from 1 to 1.6V, the VCO gain is at its maximum, approximately 6570 MHz/V. It is then recommended that the varactor voltage is kept as much as possible in this range.
VCO gain
Vdd=3.3V, LDO_en=1, VCO_IB=0
Freq [MHz]
1040
1020
1000
980
960
VCO_freq=11
940
920
VCO_freq=10
VCO_freq=01
900
VCO_freq=00
880
860
840
820
800
0
0.5
1
1.5
2
2.5
Vvaractor [V]
Figure 3: RF frequency vs. varactor voltage and VCO frequency bit
The input capacitance at the varactor pin must be taken into considerations when designing the PLL loop filter. This
can be critical when designing a loop filter with high bandwidth, which gives relatively small component values. The
input capacitance is approximately 6 pF.
For test purposes, the VCO can be bypassed by applying a differential local oscillator (LO) signal to the device on
pin CPOUT and VARIN. A resistor of 18 kΩ to ground and a series capacitor of 47 pF are needed on both pins for
proper biasing. The register bit VCO_by must be set to ‘1’.
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SX1223
4.1.4
Charge Pump
The charge pump current can be set to either 125 or 500 µA by the CP_HI bit. The default value at power-up is 125
µA (CP_HI = ‘0’). The choice of this current affects the loop filter component values (see section 4.1.5). For most
applications the lowest current mode is recommended. For those applications using a high phase detector
frequency and a high PLL bandwidth, 500 µA may provide a better solution.
4.1.5 Loop Filter
The design of the PLL filter will strongly affect the performance of the frequency synthesizer. The PLL filter is kept
external for flexibility. The parameters to be considered when designing the loop filter for the SX1223 are primarily
the modulation mode and bit rate. These will also affect the switching time and phase noise.
The frequency modulation can be done in three different ways with the SX1223, either by closed-, open loop VCO
modulation or by modulation with the internal dividers, see Table 3 and modulation selection guide in Table 35.
Modulation1 Modulation0
0
0
0
1
1
0
1
1
State
Closed loop VCO-modulation (mw1)
Open loop VCO-modulation (mw2)
Modulation by A,M and N (mw3)
Not used
Comments
VCO is phase-locked
VCO is free-running
Modulation inside PLL
Table 3: Modulation modes
R1
PCB
C1
C2
20
PCB
21
÷M
XCO
PFD
VCO
R1
C3
C2
20
PCB
21
C3
C1
R2
21
SX1223
SX1223
SX1223
XCO
R1
C3
C2
20
÷M
XCO
PFD
÷M
PFD
VCO
VCO
OL opamp
MOD
MOD
÷ N,A
Modulation mw1
÷ N,A
÷2
÷2
Modulation mw2
MOD
÷ N,A
÷2
Modulation mw3
Figure 4: Modulation modes
In closed loop VCO modulation (mw1), the PLL bandwidth needs to be sufficiently low (≈ Bit Rate / 20), so as to
prevent the VCO tracking the modulation and cancelling the modulation.
Using the dividers in mw3 mode, the PLL needs to lock on a new carrier frequency for every new data bit. Now the
PLL bandwidth needs to be sufficiently high (≈ Bit Rate / 2). It may be necessary to implement a third order filter to
futher suppress the phase detector frequency spurs,
For the open loop VCO modulation case (mw2), the PLL bandwidth can be large, as the PLL is deactivated during
the transmission burst and there is no requirement to supress the phase detector frequency
To increase the transmission time in the open loop case, a capacitor of 47 nF can be connected on pin VARIN to
ground (NPO type is advised if the transmission duration is critical). The internal opamp must be enabled to drive
this capacitor, by setting the bit OL_opamp_en to 1.
A schematic for a third order loop filter is shown in Figure 5a. For a second order filter, C3 is not connected and R2
is set to 0 Ω. When designing a third order loop filter, the internal capacitance on the VARIN pin of approximately 6
pF must be taken into consideration. Figure 5b shows the loop filter configuration for the open loop VCO modulation
case.
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SX1223
R2
CPOUT, pin 20
C1
C2
VARIN, pin 21
CPOUT, pin 20
C3
C1
VARIN, pin 21
C2
47nF
R1
b)
a)
Figure 5:
C3
R1
Loop filter for a) closed loop modulation and b) open loop modulation
4.1.6 Lock Detect
A lock detector can be enabled by setting LD_en=1. When enabled pin LD is set high, indicating that the PLL is in
lock. The lock detect signal can also be used to control the PA; if LD is low the PA is turned off and vice versa. To
enable this function, the PA_LDc_en must be set to ‘1’ (see section 4.3).
Care must be taken when monitoring the LD during data transmission using the closed loop modulation. The LD
may show that the PLL is not locked, especially when the loop filter bandwidth is too high relative to the bit rate.
4.2
MODULATOR
4.2.1 Introduction
The modulator has a high degree of flexibility, and there are thus several values that need programming. First, the
settings concerning the data bit rate must be determined, then these values will be used in the calculation of the
frequency deviation. Finally the user must check that the modulator won’t saturate with the values chosen.
4.2.2 Data Interface
The "data interface" can be programmed to synchronous or asynchronous mode (see Table 4).
Sync_en
0
1
State
DataClk pin off
DataClk pin on.
Comments
Transparent transmission of data
Bit-clock is generated by transmitter
Table 4: Synchronizer mode
In asynchronous mode only the DATAIN pin is used for transmitting the data to the SX1223.
In synchronous mode the SX1223 is defined as "Master" and provides a data clock on pin DCLK that allows the
user to utilize low cost micro controller reference frequency. The data interface is defined in such a way that all user
actions should take place on falling edges of DCLK as illustrated in Figure 6. The data are sampled by the SX1223
on the rising edges of DCLK.
DATAIN
DCLK
Figure 6:
Time diagram of the data interface in synchronous mode
Before entering into transmit mode (mw1 or mw2), it is important to set DATAIN to high impedance. The data is
provided directly to the modulation circuit and violation of this may cause abnormal behavior.
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SX1223
4.2.3 Bit Rate Setting for MW1 and MW2
The bit rate is set by first dividing the crystal oscillator frequency by an integer in the range [1..63] in a
programmable divider, then this frequency is divided further by powers of two. The equation describing the bit rate
as a function of RefClk_K and BRn is
BR =
f XTAL
(4.1)
Re fClk _ K ⋅ 23+ BRn
where:
fXTAL:
RefClk_K:
BRn:
Crystal oscillator frequency.
Integer in the range [1..63] (6 bit).
Integer in the range [0..5] (3 bit).
A procedure to determine the settings for the desired bit rate is described below:
1. Set BRn to 0.
2. Calculate RefClk_K by using this formula: Re fClk _ K =
f XTAL
BR ⋅ 23+ BRn
.
3. If RefClk_K is too high, increment n by one, and repeat step 2, above
In some cases several combinations of RefClk_K and BRn will provide the required bit rate. In these cases BRn
should be chosen with the following in mind: A lower BRn offers better waveform shaping or spectral efficiency, but
may cause modulator saturation at some bit rates.
4.2.4 Deviation Setting for MW1 and MW2
Frequency deviation is controlled by user parameters RefClk_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 RefClk_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 (4.2).
f DEV ∝
Re fClk _ K
f XTAL
(4.2)
It is assumed that K will be constant for most applications to keep bit-rate and shaping constant, although this is not
a requirement.
The control parameters of the 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 RefClk_K. The relationship is shown in
equation (4.3).
f DEV ∝
MOD _ I
2 MOD _ A
(4.3)
Finally, the VCO gain is given by equation (4.4).
KVCO =
Const1 + (Const 2 ⋅ f C ⋅ (2 − FreqBand ))
2 − FreqBand
(4.4)
where:
Const1:
Const2:
fC:
FreqBand:
− 30.6324 × 109
54.7
Carrier frequency.
Frequency band. 0: 400MHz and 1: 900MHz.
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SX1223
From equation (4.4), it can be seen that VCO is proportional to carrier frequency. MOD_I is the best parameter to
alter to counteract this effect if necessary.
Combining equations (4.2), (4.3), and (4.4) gives an expression for the frequency deviation:
∆f =
RefClk_K MOD _ I Const1 + (Const 2 ⋅ f C ⋅ (2 − FreqBand ))
⋅
⋅
f XTAL
2 − FreqBand
2 MOD _ A
(4.5)
4.2.5 Shaping for MW1 and MW2
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⋅Period-product (BT) given by:
BT = 2 BRn
(4.6)
It can be seen from this equation that a low BRn gives a low shaping factor.
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 (4.7).
MOD _ F ≤
150 × 103
BR
(4.7)
4.2.6 Modulator Saturation for MW1 and MW2
The modulator output voltage is generated with 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. The maximum value of MOD_I can be
determined by using equation (4.8).


f XTAL
MOD _ I ≤ 
⋅ 28 × 10− 6  + 1
Re
fClk
_
K


(4.8)
If it turns out that the MOD_I-range is too small for the application, the solution can be found by increasing BRn and
decreasing RefClk_K accordingly.
4.2.7 Summary of Modulator Settings for MW1 and MW2
The necessary equations needed for the use of the modulator are (4.1), (4.5), (4.6), (4.7), and (4.8). The table
below gives a summary of the meaning of the parameters.
Symbol
RefClk_K
Range
(inclusive)
1..63
BRn
MOD_F
0..5
0..3
MOD_I
MOD_A
1..31
0..4
Explanation
The crystal oscillator frequency is divided by this number to produce the modulator
clock, and it is divided further down by 8 to produce bit rate clock.
Number of extra divide-by-two for the bit rate clock.
Programmable smoothing filter after attenuator. This can be programmed in four
steps, and will produce reasonable results for the highest bit rates.
Frequency deviation. The deviation is linearly dependent on this variable.
Frequency deviation attenuator (or range selector). The attenuations are (values 0
through 4, respectively)
1 , 1 , 1 , 1 , and 1 .
1
2 4 8
16
Table 5: Modulator settings
4.2.8 Frequency deviation setting for MW3
In MW3 the modulation is done by switching between two frequency divider ratio sets: M0, N0, A0 and M1, N1, A1.
The frequency f0 will be generated using the first set and frequency f1 using the second set, corresponding to the
transmission of the two possible values ‘0’ and ‘1’.
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SX1223
The single sided frequency deviation ∆f is half of the difference between f0 and f1. Bit rates from 1.2 to 19.2 kbit/s
are achievable with this method.
4.3
POWER AMPLIFIER
The output power of the PA is programmable in 8 steps, with approximately 3 dB between each step. This is
controlled by bits PA2 to PA0 according to Table 6 below. PA2..PA0 = 111 provides the maximum output power of
typically 10 dBm.
PA2
PA1
PA0
Output power
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
21dB attenuation
18dB attenuation
15dB attenuation
12dB attenuation
9dB attenuation
6dB attenuation
3dB attenuation
Maximum power
Table 6: PA power settings
The PA is normally controlled by the two Mode bits (off for all cases other than Mode1, Mode0 = ‘11’). The PA can
in addition be controlled by the lock detector, if the bit PALDc_en is set high (and LD_en=’1’). In this case, once LD
goes high after entering the transmit mode, the PA is turned on and will remain on until a new event changing the
working mode occurs (such as a new configuration transmitted through the 3-wire interface).
During open loop VCO modulation, mw2, the PLL is deactivated during the transmission time. After an open loop
transmission, the frequency may have drifted off, and it is therefore important that the PA is turned off before the
PLL is activated. The PA behaves this way as long as PALDc_en=1. After a transmission burst, DATAIN must be
set to high impedance, the PA is turned off and the PLL is reactivated. Once LD goes high again, the PA is turned
on and a new burst of data can be transmitted.
To reduce the harmonics for passing the ETSI and FCC regulations a 3rd order LC-filter (T or Π configuration)
should be implemented between the output of the PA and the antenna port.
The ramp-up of the PA is achieved using an internal capacitor (approx. 29pF). If this is not sufficient to pass
relevant regulations, bit PAC_en can be enabled and an external capacitor connected to pin 6.
Using PA_IB3,2 and PAB_IB3,2 bits the reference current can be selected to bias the PA and the PA buffer as
shown in Table 31.
An 82kΩ resistor should be connected between pin 24 and ground for the CI bias. If the option PTAT bias source
with external resistor is chosen, an 18kΩ resistor should be connected between pin 6 and ground.
This option can not be used when PAC_en option is selected. In this case the resistor is replaced by a capacitor,
and the functionality changes as described above.
4.4
VOLTAGE REGULATORS
The SX1223 has three internal Low Dropout Regulators (LDOs) powering up different parts of the circuit, as can be
seen from the block diagram (Figure 1). The LDOs can be turned off (default setting is on) by setting the
LDO_en=’0’.
When LDO_en=’1’, the power supply range is 2.2 - 3.6 V (sv1). Power must be applied to pins 1 and 11. A good
quality factor capacitor is needed on each of the LDO output for stability (pins 3, 9 and 23). In sleep mode all the
LDOs are turned off. The interface and control blocks run on unregulated power, and the register contents will be
stored and hence the device can be programmed whilst in this mode.
When LDO_en=0, the power supply range is 2.0 - 2.5 V (sv2). Power must be applied to pin 1, 3, 9, 11 and 23. In
this case capacitors are only needed for normal noise decoupling.
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SX1223
5
SERIAL INTERFACE DEFINITION AND PRINCIPLES OF OPERATION
5.1
SERIAL CONTROL INTERFACE
A 3-wire bi-directional bus (SCK, SI, SO) is used to communicate with SX1223 and gives access to the
configuration register. SCK and SI are input signals supplied externally, for example by the microcontroller. The
SX1223 configures the SO signal as an output pin during read operation, and it is tri-stated in other modes. The
falling edge of the SCK signal is used to sample the SI pin to write data into the internal shift register of the SX1223.
The rising edge of the SCK signal is used to output data by the SX1223 to the SO pin, so the microcontroller should
sample data at the falling edge of SCK. Be aware that reading data on SO output is forbidden whilst in transmit
mode.
The signal EN must be low during the whole write and read sequences. In write mode the actual content of the
configuration register is updated at the rising edge of the EN signal. Before this, the new data is stored in temporary
registers whose content does not affect the transceiver settings.
The timing diagram of a write sequence is given in Figure 7 below. The sequence is initiated when a Start condition
is detected, that is when the SI signal is set to “0” during a period of SCK. The next bit is a read/write (R/W) bit
which should be “0” to indicate a write operation. The next 5 bits are the address of the control register A[4:0] to be
accessed, MSB first. Then, the next 8 bits are the data to be written in the register. The data on SI should change at
the rising edges of SCK, and is sampled at the falling edge of SCK. The SI line should be at “1” for at least one
clock cycle on SCK before a new write or read sequence can start. In doing this, users can do multiple registers
write without a rising EN signal in between. The duty cycle of SCK must be between 40% and 60% and the
maximum frequency of this signal is 1 MHz. Over the operating supply and temperature range, set-up and hold time
for SI on the falling edge of SCK are 200ns.
SCK
SI
A4
A3
A2
A1
A0
D7
D6
D5
D4
D3
D2
D1
D0
EN
SO
HZ
Figure 7: Write sequence into configuration register
The time diagram of a read sequence is given in figure below. The sequence is initiated when a Start condition is
detected, that is when the SI signal is set to “0” during a period of SCK. The next bit is a read/write (R/W) bit which
should be “1” to indicate a read operation. The next 5 bits are the address of the control register A[4:0] to be
accessed, MSB first. Then the data from the register are transmitted on the SO pin. The data become valid at the
rising edges of SCK and should be sampled at the falling edge of SCK. After this, the data transfer is terminated.
The SI line must stay high for at least one clock cycle on SCK to start a new write or read sequence. The typical
current drive on SO is 2mA @ 2.7V, the maximum load is CLop.
When the serial interface is not used for read or write operations, both SCK and SI should be set to “1”. Except in
read mode, SO is set to “HZ”.
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SX1223
Figure 8: Read sequence of configuration register.
5.2
CONFIGURATION AND STATUS REGISTERS
The SX1223 has several operating modes and configuration parameters which can be programmed by the user.
These modes and parameters are stored in a set of internal configuration registers that can be accessed by the
microcontroller through the 3-wire serial interface.
The detailed contents of the configuration registers are given in the next table. The value attached to each
parameter is the default value at power-up. All the undefined bits in the table below should be kept to 0.
Address
A[6:0]
0000000
Default Value
D[7:0] Hex
0x3F
0000001
0x7D
0000010
0x02
0000011
0000100
0000101
0000110
0000111
0001000
0001001
0001010
0001011
0001100
0001101
0001110
0001111
0010000
0010001
0x4B
0x0C
0x1A
0x02
0x00
0x76
0x00
0x22
0x02
0x00
0x76
0x00
0x22
0x20
0xDD
Data
D7
D6
-
D5
D4
D3
Mode [1:0]
Modulation [1:0]
-
-
-
-
D2
PA [2:0]
Freq_Band
XCOcap_en
LDO_en
OL_opamp_
en
PAC_en
XCO_Quick_
Start
XCO_High_
Current
CP_HI
D1
D0
ClkOut_en
Sync_en
PA_LDc_en
LD_en
VCO_freq [1:0]
Mod_I [4:0]
Mod_A [2:0]
Mod_F [2:0]
BRn [2:0]
RefClk_K [5:0]
A0 [5:0]
-
-
N0 [11.8]
N0 [7:0]
-
-
-
-
M0 [11:8]
M0 [7:0]
-
-
A1 [5:0]
-
-
N1 [11:8]
N1 [7:0]
-
-
-
M1 [11:8]
M1 [7:0]
Prescal_s
VCO_by
VCO_IB [2:0]
PA_IB [3:0]
-
-
-
PAB_IB [3:0]
Table 7: Contents of the configuration registers and their values at power-on
5.2.1 Operating Modes
The SX1223 can be programmed into four different modes by the Mode1 and Mode0 bits, as illustrated in Table 8.
Add Bits
0
6-5
Mode1
0
0
1
1
Mode0
0
1
0
1
Mode
Sleep mode
Standby mode
Synthesizer mode
Transmit mode
Description
All blocks off, Register configuration kept (default)
Crystal oscillator enabled
Crystal oscillator, Frequency synthesizer enabled
Crystal oscillator, Frequency synthesizer, PA enabled
Table 8: SX1223 Operating Modes
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SX1223
5.2.2 Other Settings
The tables below give the definition of all the parameters of the configuration registers besides the working modes.
Add Bits
0
4-2
PA2
0
0
0
0
1
1
1
1
PA1
0
0
1
1
0
0
1
1
PA0
0
1
0
1
0
1
0
1
State
21dB attenuation
18dB attenuation
15dB attenuation
12dB attenuation
9dB attenuation
6dB attenuation
3dB attenuation
Max output (default)
Table 9: Power amplifier output power
Add
0
Bit ClkOut_en
1
0
1
State
ClkOut off
Comments
Output is 0 volt on pin CLKOUT.
A clock at XCO frequency divided by 16 is
available on pin CLKOUT. (default)
ClkOut on
Table 10: Output clock
Add
0
Bit
0
Sync_en
0
State
DCLK pin off
1
DCLK pin on
Comments
Transparent transmission of data
Bit-clock is generated by transceiver
(default)
Table 11: Synchronizer mode
Add
1
Bit Modulation1 Modulation0 State
7-6
Closed loop VCO-modulation (mw1)
0
0
0
1
1
1
0
1
Open loop VCO-modulation (mw2)
Modulation by M, N and A (mw3)
Not used
Comments
VCO is phase-locked
VCO is free-running
(default)
Modulation inside PLL
Table 12: Modulation mode
Add
1
Bit
5
FreqBand
0
1
Comments
RF frequency 425-475 MHz
RF frequency 850-950 MHz (default)
Table 13: Frequency band
Add
1
Bit
4
XCOcap_en
0
1
Comments
Internal capacitors for the crystal oscillator turned off
Internal capacitors for the crystal oscillator turned on, external capacitors not needed
(default)
Table 14: XCO internal capacitor
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SX1223
Add
2
Bit XCO_quick_start XCO_high_current
4-3
0
0
0
1
1
0
1
1
Comments
Normal XCO bias current (default)
Higher XCO bias current
Quick start of XCO with normal bias current in steady state
Quick start of XCO with higher bias current in steady state
Table 15: XCO start-up control
Add
1
Bit
3
LDO_en
0
1
Comments
LDO turned off, min/max VDD is 2.0/2.5 V
LDO turned on, min/max VDD is 2.2/3.6 V (default)
Table 16: Low DropOut voltage regulator on/off
Add
1
Bit OL_opamp_en State
2
0
Open loop opamp off
Open loop opamp on
(default)
1
Comments
When opamp is enabled, a capacitor can be
added to the varactor pin that will increase the
transmission time in open loop modulation (mw2)
Table 17: Open loop opamp on/off
Add
2
Bit
5
PA_C
0
1
Comments
Startup time of PA controlled by internal capacitor; PTAT source using the
resistor connected to pin6 can be used (default)
Startup time of PA controlled by external capacitor connected to pin 6; PTAT
source using the resistor connected to pin6 is not available
Table 18: PA start-up control
Add
1
Bit
1
PALDc_en Comments
PA is only controlled by Mode1 and Mode0: PA on in transmit mode
0
(Mode1=Mode0=1) (default)
1
In transmit mode, PA is turned on/off by Lock Detect (i.e. LD=1 -> PA on)
Table 19: Lock Detect controlled PA
Add
1
Bit
0
LD_en
0
1
State
LD off
LD on
Comments
Output is low
A high indicate a PLL lock (default)
Table 20: Lock Detector
Add
2
Bit
2
CP_HI
0
1
Comments
PLL charge pump current is 125 µA (default)
PLL charge pump current is 500 µA
Table 21: Charge pump current
Add Bits VCO_freq1 VCO_freq0 Comments (*)
2
1-0
0
0
Setting for 850 MHz
0
1
Setting for 868 MHz
1
0
Setting for 915 MHz (default)
1
1
Setting for 950 MHz
(*) Assuming FreqBand=1. When FreqBand=0, the RF frequency is halved.
Table 22: VCO frequency
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SX1223
Add Bits
3
7-3
MOD_I
1..31
Comments
The deviation frequency is linearly dependent of MOD_I
Table 23: Modulator current setting for frequency deviation
Add Bits
3
2-0
MOD_A
0..4
Comments
Frequency deviation attenuator (or range selector). The attenuations are
(values 0 through 4, respectively)
1 , 1 , 1 , 1 , and 1 .
1
2 4 8
16
Table 24: Modulator attenuator setting for frequency deviation
Add Bits
4
5-3
BRn
0..5
Comments
The bit rate clock is set by dividing the crystal oscillator frequency by
RefClk_K*2^(3+BRn)
Table 25: Bit Rate setting
Add Bits
4
2-0
MOD_F
0..3
Comments
Programmable smoothing filter after attenuator. This can be programmed in
four steps, and will produce reasonable results for the highest bit rates.
Table 26: Modulator filter setting
Add Bits
5
5-0
RefClk_K Comments
The crystal oscillator is divided by this number to produce modulator clock and
1..63
it is divided further down by 2^(3+BRn) to produce the bit rate clock.
Table 27: Modulator and Bit Rate clock setting
Add
16
Bit
4
Prescal_s
0
1
State
Comments
(default)
Reserved.
Prescaler enabled
f XCO
=
(16 ⋅ N + A)
M ⋅ ( 2 − FreqBand )
f RF
Table 28: Prescaler enable bit
“1” should be written in Prescal_s register to operate SX1223 PLL dividers.
5.2.3 Optional and Test Parameters
In most applications, the user has only to be concerned with the parameters given in sections 5.2.1 and 5.2.2.
However some options and test modes are available for special purposes. They are described in the tables below.
Add Bits
16
7-5
VCO_IB2
1
1
0
0
VCO_IB1
1
0
1
0
VCO_IB0
1
1
1
0
Comments - default = [0 0 1]
Bias setting for 850 MHz
Bias setting for 868 MHz
Bias setting for 915 MHz
Bias setting for 950 MHz
Table 29: VCO bias
The two VCO_freq bits have to be programmed by the user according to the selected frequency band, whereas the
three VCO_IB bits can be either forced by the user or set automatically by the circuit which will select the
combination having the best phase noise. This automatic setting can be enabled by setting the three VCO_IB bits to
‘0’.
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SX1223
Add
16
Bit
3
VCO_by
0
1
State
VCO is active (default)
VCO is bypassed
Comment
When VCO is bypassed, a differential signal can be
applied to the circuit using pin CPOUT and VARIN
Table 30: VCO bypass bit
Add Bits PA_IB3 PA_IB2
17
7-6
0
0
0
1
1
0
1
1
Add Bits PA_IB1 PA_IB0
17
5-4
0
0
0
1
1
0
1
1
Add Bits PAB_IB3 PAB_IB2
17
3-2
0
0
0
1
1
0
1
1
Add Bits PAB_IB1 PAB_IB0
17
1-0
0
0
0
1
1
0
1
1
State
PA uses bias current from PTAT bias source, external resistor (Pin 6)
PA uses bias current from CI bias source, external resistor (Pin 24)
PA uses bias current from internal bias source, PTAT
PA uses bias current from internal bias source, PTAT + CI (default)
State
PA bias current setting, lowest bias current
PA bias current setting (default)
PA bias current setting
PA bias current setting, highest bias current
State
PAbuffer uses bias current from PTAT bias source, external resistor (Pin 6)
PAbuffer uses bias current from CI bias source, external resistor (Pin 24)
PAbuffer uses bias current from internal bias source, PTAT
PAbuffer uses bias current from internal bias source, PTAT + CI (default)
State
PAbuffer bias current setting, lowest bias current
PAbuffer bias current setting (default)
PAbuffer bias current setting
PAbuffer bias current setting, highest bias current
Table 31: PA and PAbuffer bias current setting
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SX1223
6
APPLICATION INFORMATION
This section provides details of the recommended components values for the frequency dependant blocks of the
SX1223. Note that these values are dependent upon circuit layout and PCB structure.
6.1
MATCHING NETWORK OF THE TRANSMITTER
The optimum load impedances for 10 dBm output power at the three main frequencies are given in the following
table.
PA optimum load
434 MHz
869 MHz
915 MHz
19.4-j2.6
23.5-j1
23.5+j8
Table 32: Optimum load impedances for 10 dBm output power
The schematic of the recommended matching network at the output of the transmitter is given in Figure 9 on the
next page.
CT2
SX1223
CT4
LT1
CT1
CT3
Figure 9: Transmitter output network
The Π-section is used to provide harmonic filtering in order to satisfy FCC and ETSI regulations.
The typical component values of this matching circuit are given below.
Name
Typical Value
for 434 MHz
Typical Value
for 869 MHz
Typical Value
for 915 MHz
Tolerance
CT1
6.8pF
6.8 pF
6.8 pF
± 5%
CT2
1pF
NC
NC
± 5%
CT3
10pF
15 pF
33 pF
± 5%
CT4
10pF
6.8 pF
4.7 pF
± 5%
LT1
22nH
4.7 nH
4.7 nH
± 5%
Table 33: Typical component values for the recommended matching network at the output of the transmitter
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SX1223
6.2
REFERENCE CRYSTAL FOR THE FREQUENCY SYNTHESIZER
The crystal for the reference oscillator of the frequency synthesizer should have the following typical characteristics:
Name
Description
Min. value
Typ. value
Max. value
Fs
Nominal frequency
-
16.0 MHz
(fundamental)
-
CL
Load capacitance for fs (on-chip)
-
9 pF
-
Rm
Motional resistance
-
-
40Ω
Cm
Motional capacitance
-
-
30 fF
C0
Shunt capacitance
-
-
7 pF
Table 34: Crystal characteristics
6.3
LOOP FILTER COMPONENTS
The loop filter component values used in MW2 mode for specification validation are presented below; (see fig.5b)
R1
12kΩ
6.4
C1
470pF
C2
4.7nF
C3
33nF
RECOMMENDED MODULATION CONDITIONS
Bit
rate
[kb/s]
Frequency
deviation
[kHz]
Modulation
type
Max. carrier
frequency
step
Coding
Allowed transmission mode
1.2
5 to 255
mw3
Continuous
5 to 255
4.8
5 to 255
Up to 300
kHz,
not regularly
spaced
NRZ
2.4
9.6
10 to 255
19.2
20 to 255
32.8
40 to 255
mw1
≤ 100 kHz
Manchester
Continuous
100 to 255
mw2
≤ 100 kHz
NRZ
Burst (1 kbits for ∆f ≥ 100 kHz)
38.4
76.8
153.6
40 to 255
mw1
≤ 100 kHz
Manchester
Continuous
100 to 255
mw2
≤ 100 kHz
NRZ
Burst (1 kbits for ∆f ≥ 100 kHz)
80 to 255
mw1
≤ 100 kHz
Manchester
Continuous
100 to 255
mw2
≤ 100 kHz
NRZ
Burst (2 kbits for ∆f ≥ 100 kHz)
200 to 255
mw1
≤ 100 kHz
Manchester
Continuous
100 to 255
mw2
≤ 100 kHz
NRZ
Burst (4 kbits for ∆f ≥ 100 kHz)
Table 35: Modulation Type Selection
© Semtech 2007
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22
SX1223
6.5
TYPICAL APPLICATION SCHEMATICS
C7
VDD
R2
C8
C6
R1
C9
VDD
24
21
20
19
Slave Out
SO
CPOUT
VARIN
VSSF
VDD
C4
22
VDDF
C5
CIBIAS
1
23
SI
2
VSSP
/EN
3
VSSP
DCLK
PTAT/PAC
7
CLKOUT
8
9
10
11
Slave In
17
/Select SPI
16
15
14
13
Serial Clock
Tx Data Input
Tx Data Clock
Clock Output
PLL Lock Detect
LD
C1
DATAIN
VDD
NC
C3
TQFN24
4x4
VSSD
6
RFOUT
VDDD
C2
SCK
XTA
5
L1
SX1223
XTB
4
VDDP
18
12
VDD
C11
C10
Figure 10: Application Schematics
Note: refer to chapter 4.3 for pin 6.
Please contact Semtech for applications schematics and bills of materials for Reference Designs.
© Semtech 2007
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23
SX1223
7
PACKAGING INFORMATION
SX1223 comes in a 24-pin RoHS green TQFN 4x4 package as shown in Figure 11 below.
Figure 11: Package dimensions
The exposed die pad on the bottom of the chip should be soldered. Please contact Semtech for foot print
recommendations and PCB gerber files of Semtech reference designs.
© Semtech 2007
www.semtech.com
24
SX1223
© Semtech 2006
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Contact Information
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Phone (805) 498-2111 Fax : (805) 498-3804
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