TI1 CC1150-RTY1 Low power sub-1 ghz rf transmitter Datasheet

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CC1150
SWRS037B – JANUARY 2006 – REVISED MARCH 2015
CC1150 Low Power Sub-1 GHz RF Transmitter
1 Device Overview
1.1
Features
1
• Small Size
– QLP 4-mm × 4-mm Package, 16 Pins
• True Single Chip UHF RF Transmitter
• Frequency Bands
– 300 to 348 MHz
– 400 to 464 MHz
– 800 to 928 MHz
• Programmable Data Rate Up to 500 kBaud
• Low Current Consumption
• Programmable Output Power Up to +10 dBm for
All Supported Frequencies
• Programmable Baseband Modulator
• Ideal For Multi-channel Operation
• Very Few External Components
– Completely On-chip Frequency Synthesizer
– No External Filters Needed
• Configurable Packet Handling Hardware
• Suitable for Frequency Hopping Systems Due to a
Fast Settling Frequency Synthesizer
• Optional Forward Error Correction with Interleaving
1.2
•
•
•
•
•
Applications
Ultra-low Power UHF Wireless Transmitters
Operating in the 315-, 433-, 868-, and 915-MHz
ISM/SRD bands
AMR – Automatic Meter Reading
Consumer Electronics
RKE – Remote Keyless Entry
1.3
• 64-byte TX Data FIFO
• Suited for Systems Compliant with EN 300 220
and FCC CFR Part 15
• Many Powerful Digital Features Allow a Highperformance RF system to be made Using an
Inexpensive Microcontroller
• Efficient SPI interface: All Registers Can be
Programmed With One "Burst" Transfer
• Integrated Analog Temperature Sensor
• Lead-free “Green” Package
• Flexible Support for Packet Oriented Systems
– On-chip Support for Sync-Word Insertion,
Flexible Packet Length and Automatic CRC
Handling
• OOK and Flexible ASK Shaping Supported
• 2-FSK, GFSK and MSK Supported
• Optional Automatic Whitening of Data
• Support for Asynchronous Transparent Transmit
Mode for Backwards Compatibility with Existing
Radio Communication Protocols
•
•
•
•
•
Low Power Telemetry
Home and Building Automation
Wireless Alarm and Security Systems
Industrial Monitoring and Control
Wireless Sensor Networks
Description
The CC1150 is a true single-chip UHF transmitter designed for very low power wireless applications. The
circuit is mainly intended for the ISM (Industrial, Scientific and Medical) and SRD (Short Range Device)
frequency bands at 315-, 433-, 868-, and 915-MHz, but can easily be programmed for operation at other
frequencies in the 300 to 348 MHz, 400 to 464 MHz and 800 to 928 MHz bands.
The RF transmitter is integrated with a highly configurable baseband modulator. The modulator supports
various modulation formats and has a configurable data rate up to 500 kBaud. The CC1150 device
provides extensive hardware support for packet handling, data buffering and burst transmissions.
The main operating parameters and the 64-byte transmit FIFO of CC1150 can be controlled via an SPI
interface. In a typical system, the CC1150 device will be used together with a microcontroller and a few
additional passive components.
CC1150 is part of the SmartRF™ technology platform based on 0.18-μm CMOS technology from Texas
Instruments.
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
CC1150
SWRS037B – JANUARY 2006 – REVISED MARCH 2015
www.ti.com
Table 1-1. Device Information (1)
(1)
1.4
PART NUMBER
PACKAGE
BODY SIZE
CC1150
VQFNP (16)
4.00 mm × 4.00 mm
For more information, see Section 8, Mechanical Packaging and Orderable Information.
Functional Block Diagram
BIAS
XOSC
DIGITAL
INTERFACE
TO MCU
TX FIFO
PACKET
HANDLER
RF_N
FREQ
SYNTH
PA
FEC /
INTERLEAVER
RF_P
MODULATOR
RADIO CONTROL
SCLK
SO (GDO1)
SI
CSn
GDO0 (ATEST)
RBIAS XOSC_Q1 XOSC_Q2
2
Device Overview
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Table of Contents
1
2
3
Device Overview ......................................... 1
5.7
Data Rate Programming ............................ 18
1.1
Features .............................................. 1
5.8
Packet Handling Hardware Support ................. 19
1.2
Applications ........................................... 1
5.9
Modulation Formats ................................. 23
1.3
Description ............................................ 1
5.10
Forward Error Correction with Interleaving .......... 24
1.4
Functional Block Diagram ............................ 2
5.11
Radio Control ........................................ 26
Revision History ......................................... 4
Terminal Configuration and Functions .............. 5
5.12
Data FIFO ........................................... 29
5.13
Frequency Programming
Pin Attributes ......................................... 5
5.14
VCO ................................................. 31
3.1
4
6
5.15
Voltage Regulators .................................. 32
Absolute Maximum Ratings .......................... 6
5.16
Output Power Programming......................... 32
4.2
ESD Ratings .......................................... 6
5.17
General Purpose and Test Output Control Pins .... 33
4.3
Recommended Operating Conditions ................ 6
5.18
Asynchronous and Synchronous Serial Operation .. 35
4.4
.............................. 6
Current Consumption ................................. 7
RF Transmit .......................................... 7
Crystal Oscillator ..................................... 8
Frequency Synthesizer Characteristics .............. 8
Analog Temperature Sensor ......................... 9
DC Characteristics ................................... 9
Power-On Reset .................................... 10
5.19
System Considerations and Guidelines ............. 36
5.20
Memory .............................................. 38
4.5
4.6
4.7
4.8
4.9
4.10
4.11
4.12
5
31
4.1
Specifications
............................................
...........................
General Characteristics
6
7
5.2
5.3
5.4
5.5
5.6
............................................
Functional Block Diagram ...........................
Configuration Overview .............................
Configuration Software ..............................
4-wire Serial Configuration and Data Interface .....
Microcontroller Interface and Pin Configuration .....
Overview
6.1
Application Information .............................. 51
6.2
Design Requirements
6.3
PCB Layout Recommendations ..................... 55
...............................
53
Device and Documentation Support ............... 58
7.1
Device Support ...................................... 58
7.2
Documentation Support ............................. 58
7.3
Trademarks.......................................... 59
7.4
Electrostatic Discharge Caution ..................... 59
11
7.5
Export Control Notice
11
7.6
Glossary ............................................. 59
Thermal Resistance Characteristics for VQFNP
Package ............................................. 10
Detailed Description ................................... 11
5.1
Applications, Implementation, and Layout........ 51
11
8
...............................
59
12
Mechanical Packaging and Orderable
Information .............................................. 59
13
8.1
Packaging Information
..............................
59
17
Table of Contents
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2 Revision History
This data manual revision history highlights the changes made to the SWRS037A device-specific data
manual to make it an SWRS037B revision.
Changes from January 1, 2006 to February 19, 2015
•
4
Updated RST package to RGV.
Page
..................................................................................................
Revision History
58
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3 Terminal Configuration and Functions
AVDD
RBIAS
SI
DGUARD
The CC1150 pinout is shown in Figure 3-1 and Table 3-1
16 15 14 13
SCLK 1
12 AVDD
SO (GDO1) 2
11 RF_N
DVDD 3
10 RF_P
DCOUPL 4
9 CSn
XOSC_Q1
AVDD
7
8
XOSC_Q2
6
GDO0 (ATEST)
5
GND
Exposed die
attach pad
Figure 3-1. Pinout Top View
3.1
Pin Attributes
Table 3-1. Pin Attributes (1)
(1)
(2)
PIN NO.
PIN NAME
TYPE
DESCRIPTION
1
SCLK
Digital Input
2
SO (GDO1)
Digital Output
Serial configuration interface, data output.
Optional general output pin when CSn is high.
3
DVDD
Power (Digital)
1.8-V to 3.6-V digital power supply for digital I/Os and for the digital
core voltage regulator.
4
DCOUPL (2)
Power (Digital)
1.6-V to 2.0-V digital power supply output for decoupling.
5
XOSC_Q1
Analog I/O
6
AVDD
Power (Analog)
7
XOSC_Q2
Analog I/O
Crystal oscillator pin 2.
Digital output pin for general use:
•
Test signals
•
FIFO status signals
•
Clock output, down-divided from XOSC
•
Serial input TX data
Also used as analog test I/O for prototype/production testing.
Serial configuration interface, clock input.
Crystal oscillator pin 1, or external clock input.
1.8-V to 3.6-V analog power supply connection.
8
GDO0
(ATEST)
Digital I/O
9
CSn
Digital Input
10
RF_P
RF I/O
Positive RF output signal from PA.
11
RF_N
RF I/O
Negative RF output signal from PA.
12
AVDD
Power (Analog)
1.8-V to 3.6-V analog power supply connection.
13
AVDD
Power (Analog)
1.8-V to 3.6-V analog power supply connection.
14
RBIAS
Analog I/O
15
DGUARD
Power (Digital)
16
SI
Digital Input
Serial configuration interface, chip select.
External bias resistor for reference current.
Power supply connection for digital noise isolation.
Serial configuration interface, data input.
The exposed die attach pad must be connected to a solid ground plane as this is the main ground connection for the chip.
This pin is intended for use with the CC1150 only. It can not be used to provide supply voltage to other devices.
Terminal Configuration and Functions
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4 Specifications
Absolute Maximum Ratings (1) (2)
4.1
over operating free-air temperature range (unless otherwise noted)
MIN
MAX
UNIT
CONDITION
All supply pins must have the same
voltage
Supply voltage
–0.3
3.6
V
Voltage on any digital pin
–0.3
VDD + 0.3, max 3.6
V
Voltage on the pins RF_P, RF_N and
DCOUPL
–0.3
2.0
V
Voltage ramp-up
120
kV/µs
Input RF level
+10
dBm
150
°C
Storage temperature range, Tstg
(1)
(2)
–50
Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under recommended operating
conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
All voltage values are with respect to VSS, unless otherwise noted.
4.2
ESD Ratings
VALUE
V(ESD)
(1)
(2)
4.3
Electrostatic discharge
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001
(1) (2)
Charged-device model (CDM)
< 500
250
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. Manufacturing with
less than 500-V HBM is possible with the necessary precautions.
According to JEDEC STD 22, method A114, Human Body Model
Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
MAX
UNIT
Operating temperature
–40
85
°C
Operating supply voltage
1.8
3.6
V
All supply pins must have the same
voltage
TYP
CONDITION
4.4
CONDITION
General Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
Frequency range
MIN
MAX
UNIT
300
348
MHz
400
464
MHz
800
928
MHz
1.2
500
kBaud
2-FSK
1.2
250
kBaud
GFSK, OOK and ASK
kBaud
(Shaped) MSK (also known as
differential offset QPSK)
Optional Manchester encoding (the
data rate in kbps will be half the
baud rate)
Data rate
26
6
500
Specifications
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4.5
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Current Consumption
Tc = 25°C, VDD = 3.0 V if nothing else stated. All measurement results are obtained using the CC1150EM reference design
(see [1] and [2]).
PARAMETER
Current consumption
Current consumption, 315 MHz
TYP
UNIT
CONDITION
200
nA
Voltage regulator to digital part off, register values lost (SLEEP state)
222
µA
Voltage regulator to digital part on, all other modules in power down
(XOFF state)
1.1
mA
Only voltage regulator to digital part and crystal oscillator running
(IDLE state)
7.7
mA
Only the frequency synthesizer running (FSTXON state). This
current consumption also representative for the other intermediate
states when going from IDLE until reaching TX, and frequency
calibration states
25.6
mA
Transmit mode, +10 dBm output power (0xC4)
14.1
mA
Transmit mode, 0 dBm output power (0x60)
See more in Section 5.16 and DN012 [3].
26.1
Current consumption, 433 MHz
mA
14.6
Transmit mode, +10 dBm output power (0xC2)
Transmit mode, 0 dBm output power (0x60)
See more in Section 5.16 and DN012 [3].
29.3
Current consumption, 868 MHz
mA
15.5
Transmit mode, +10 dBm output power (0xC3)
Transmit mode, 0 dBm output power (0x60)
See more in Section 5.16 and DN012 [3].
Current consumption, 915 MHz
29.3
mA
Transmit mode, +10 dBm output power (0xC0)
15.2
mA
Transmit mode, 0 dBm output power (0x50)
See more in Section 5.16 and DN012 [3].
4.6
RF Transmit
Tc = 25°C, VDD = 3.0 V, if nothing else stated. All measurement results are obtained using the CC1150EM reference design
(see [1] and [2]).
PARAMETER
Differential load
impedance
TYP
MAX
UNIT
315 MHz
122 + j31
Ω
433 MHz
116 + j41
Ω
86.5 +
j43
Ω
868/915 MHz
Output power, highest setting
Output power, lowest setting
+10
–30
CONDITION
Differential impedance as seen from the RFport (RF_P and RF_N) towards the antenna.
Follow the CC1150EM reference design
(see [1] and [2]).
dBm
Output power is programmable, and full
range is available across all frequency
bands. Output power may be restricted by
regulatory limits. See also
DN006 [5].
Delivered to a 50-Ω single-ended load via
CC1150 EM reference design (see [1] and
[2]) RF matching network. Maximum output
power can be increased 1 to 2 dB by using
wire-wound inductors instead of multilayer
inductors in the balun and filter circuit for the
868/915 MHz band, see more in DN017 [6].
dBm
Output power is programmable, and full
range is available across all frequency
bands.
Delivered to a 50 Ω single-ended load via
CC1150 EM reference design (see [1] and
[2]) RF matching network.
Specifications
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RF Transmit (continued)
Tc = 25°C, VDD = 3.0 V, if nothing else stated. All measurement results are obtained using the CC1150EM reference design
(see [1] and [2]).
PARAMETER
Spurious
emissions and
harmonics (1),
433/868 MHz
Spurious emissions,
315/915 MHz
Harmonics 315 MHz
Harmonics 915 MHz
MAX
UNIT
25 MHz to 1 GHz
TYP
–36
dBm
47 to 74 MHz,
87.5 to 118 MHz,
174 to 230 MHz,
470 to 862 MHz
–54
dBm
Otherwise above 1 GHz
–30
dBm
< 200 µV/m at 3 m below
960 MHz
–49.2
dBm
EIRP
< 500 µV/m at 3 m above
960 MHz
–41.2
dBm
EIRP
2nd, 3rd and 4th harmonic
–20
dBc
5th harmonic
–41.2
dBm
2nd harmonic
–20
dBc
–41.2
dBm
3rd, 4th, and 5th harmonic
TX latency
(1)
8
CONDITION
Whe output power is maximum
6 mV/m at 3 m (–19.6 dBm EIRP)
With +10 dBm output power
Serial operation. Time from sampling the
data on the transmitter data input pin until it
is observed on the RF output ports.
Bits
Note that close-in spurs vary with centre frequency and limits the frequencies and output power level which the CC1150 can operate at
without violating regulatory restrictions. See also Section 6.2.5 for information regarding additional filtering.
4.7
Crystal Oscillator
Tc = 25°C, VDD = 3.0 V if nothing else is stated. All measurement results obtained using the CC1150EM reference design
(see [1] and [2]).
PARAMETER
Crystal frequency
MIN
TYP
MAX
UNIT
26
26
27
MHz
Tolerance
±40
Load capacitance
10
13
ESR
Start-up time
4.8
CONDITION
This is the total tolerance including a) initial
tolerance, b) aging and c) temperature
dependence.
ppm
20
pF
100
Ω
150
The acceptable crystal tolerance depends on
RF frequency and channel spacing /
bandwidth
Simulated over operating conditions
Measured on the CC1150EM reference
design (see [1] and [2]). This parameter is to
a large degree crystal dependent.
µs
Frequency Synthesizer Characteristics
Tc = 25°C, VDD = 3.0 V if nothing else is stated. All measurement results obtained using the CC1150EM reference design
(see [1] and [2]).
PARAMETER
Programmed frequency
resolution
MIN
397
TYP
MAX
16
FXOSC / 2
412
UNIT
CONDITION
Hz
26 MHz to 27 MHz crystals. The resolution
(in Hz) is equal for all frequency bands.
Given by crystal used. Required accuracy
(including temperature and aging) depends
on frequency band and channel bandwidth /
spacing.
Synthesizer frequency tolerance
±40
ppm
RF carrier phase noise
–82
dBc/Hz
@ 50 kHz offset from carrier,
carrier at 868 MHz
RF carrier phase noise
–86
dBc/Hz
@ 100 kHz offset from carrier,
carrier at 868 MHz
8
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Frequency Synthesizer Characteristics (continued)
Tc = 25°C, VDD = 3.0 V if nothing else is stated. All measurement results obtained using the CC1150EM reference design
(see [1] and [2]).
PARAMETER
MIN
TYP
MAX
UNIT
CONDITION
RF carrier phase noise
–90
dBc/Hz
@ 200 kHz offset from carrier,
carrier at 868 MHz
RF carrier phase noise
–98
dBc/Hz
@ 500 kHz offset from carrier,
carrier at 868 MHz
RF carrier phase noise
–106
dBc/Hz
@ 1 MHz offset from carrier,
carrier at 868 MHz
RF carrier phase noise
–113
dBc/Hz
@ 2 MHz offset from carrier,
carrier at 868 MHz
RF carrier phase noise
–119
dBc/Hz
@ 5 MHz offset from carrier,
carrier at 868 MHz
RF carrier phase noise
–127
dBc/Hz
@ 10 MHz offset from carrier,
carrier at 868 MHz
PLL turn-on / hop time
85.1
88.4
88.4
µs
Time from leaving the IDLE state until
arriving in the FSTXON or TX state, when
not performing calibration.
Crystal oscillator running.
18739
PLL calibration time
694
4.9
721
XOSC
cycles
Calibration can be initiated manually or
automatically before entering or after leaving
TX.
µs
Min/typ/max time is for 27/26/26 MHz crystal
frequency.
721
Analog Temperature Sensor (1)
Tc = 25°C, VDD = 3.0 V if nothing else is stated.
PARAMETER
MIN
TYP
MAX
UNIT
CONDITION
Output voltage at –40°C
0.651
V
Output voltage at 0°C
0.747
V
Output voltage at +40°C
0.847
V
Output voltage at +80°C
0.945
V
Temperature coefficient
2.45
mV/°C
Fitted from –20°C to +80°C
°C
From –20°C to +80°C
when using
2.45 mV / °C, after 1-point
calibration at room
temperature
Absolute error in calculated temperature
–2
(2)
2
Current consumption increase when
enabled
(1)
(2)
(2)
0.3
mA
It is necessary to write 0xBF to the PTEST register to use the analog temperature sensor in the IDLE state.
Indicated minimum and maximum error with 1-point calibration is based on simulated values for typical process parameters
4.10 DC Characteristics
Tc = 25°C if nothing else stated.
MIN
MAX
UNIT
Logic "0" input voltage
DIGITAL INPUTS/OUTPUTS
0
0.7
V
Logic "1" input voltage
VDD – 0.7
VDD
V
CONDITION
Logic "0" output voltage
0
0.5
V
For up to 4 mA output current
Logic "1" output voltage
VDD – 0.3
VDD
V
For up to 4 mA output current
Logic "0" input current
N/A
–1
µA
Input equals 0 V
Logic "1" input current
N/A
1
µA
Input equals VDD
Specifications
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4.11 Power-On Reset
For proper Power-On-Reset functionality, the power supply must comply with the requirements in this table. Otherwise, the
chip should be assumed to have unknown state until transmitting an SRES strobe over the SPI interface. See Section 5.11.1
for a description of the recommended start-up sequence after turning power on.
PARAMETER
MIN
Power up ramp-up time
Power-off time
TYP
MAX
UNIT
5
ms
From 0 V until reaching 1.8 V
ms
Minimum time between power on and
power off
1
CONDITION
4.12 Thermal Resistance Characteristics for VQFNP Package
°C/W (1)
NAME
DESCRIPTION
RθJC(top)
Junction-to-case (top)
54.0
RθJB
Junction-to-board
25.1
RθJA
Junction-to-free air
48.3
PsiJT
Junction-to-package top
1.6
PsiJB
Junction-to-board
25.2
RθJC(bottom)
Junction-to-case (bottom)
6.3
(1)
(2)
10
(2)
°C/W = degrees Celsius per watt.
These values are based on a JEDEC-defined 2S2P system (with the exception of the Theta JC [RθJC] value, which is based on a
JEDEC-defined 1S0P system) and will change based on environment as well as application. For more information, see these
EIA/JEDEC standards:
• JESD51-2, Integrated Circuits Thermal Test Method Environmental Conditions - Natural Convection (Still Air)
• JESD51-3, Low Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
• JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
• JESD51-9, Test Boards for Area Array Surface Mount Package Thermal Measurements
Power dissipation of 2 W and an ambient temperature of 70ºC is assumed.
Specifications
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5 Detailed Description
5.1
Overview
The CC1150 transmitter is based on direct synthesis of the RF frequency. The frequency synthesizer
includes a completely on-chip LC VCO.
A crystal is to be connected to XOSC_Q1 and XOSC_Q2. The crystal oscillator generates the reference
frequency for the synthesizer, as well as clocks for the digital part. A 4-wire SPI serial interface is used for
configuration and data buffer access. The digital baseband includes support for channel configuration,
packet handling and data buffering.
5.2
Functional Block Diagram
BIAS
XOSC
DIGITAL
INTERFACE
TO MCU
TX FIFO
PACKET
HANDLER
RF_N
FREQ
SYNTH
PA
FEC /
INTERLEAVER
RF_P
MODULATOR
RADIO CONTROL
SCLK
SO (GDO1)
SI
CSn
GDO0 (ATEST)
RBIAS XOSC_Q1 XOSC_Q2
Figure 5-1. CC1150 Simplified Block Diagram
5.3
Configuration Overview
CC1150 can be configured to achieve optimum performance for many different applications. Configuration
is done using the SPI interface. The following key parameters can be programmed:
• Power-down and power-up mode
• Crystal oscillator power up and power down
• Transmit mode
• RF channel selection
• Data rate
• Modulation format
• RF output power
• Data buffering with 64-byte transmit FIFO
• Packet radio hardware support
• Forward Error Correction with interleaving
• Data Whitening
Details of each configuration register can be found in Section 5.20.
Figure 5-2 shows a simplified state diagram that explains the main CC1150 states, together with typical
usage and current consumption. For detailed information on controlling the CC1150 state machine, and a
complete state diagram, see Section 5.11.
Detailed Description
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Sleep
SPWD
SIDLE
Default state when the radio is not
receiving or transmitting. Typ.
current consumption: 1.1 mA.
SCAL
Used for calibrating frequency
synthesizer upfront (entering
Manual freq.
transmit mode can then be
synth. calibration
done quicker). Transitional
state. Typ. current
consumption: 7.7 mA.
Frequency synthesizer is on,
ready to start transmitting.
Transmission starts very
quickly after receiving the STX
command strobe.Typ. current
consumption: 7.7 mA.
SFSTXON
Lowest power mode.
Register values are lost.
Current consumption typ
200nA.
CSn=0
IDLE
SXOFF
CSn=0
Crystal
oscillator off
SRX or STX or SFSTXON
Frequency
synthesizer startup,
optional calibration,
settling
All register values are
retained. Typ. current
consumption; 0.22 mA.
Frequency synthesizer is turned on, can optionally be
calibrated, and then settles to the correct frequency.
Transitional state. Typ. current consumption: 7.7 mA.
Frequency
synthesizer on
STX
STX
TXOFF_MODE=01
Typ. current consumption 868 MHz:
14 mA at -10 dBm output,
15 mA at 0 dBm output,
24 mA at +7 dBm output,
29 mA at +10 dBm output.
Transmit mode
TXOFF_MODE=00
In FIFO-based modes,
transmission is turned off and
this state entered if the TX
FIFO becomes empty in the
middle of a packet. Typ.
current consumption: 1.1 mA.
TX FIFO
underflow
Optional transitional state. Typ.
Optional freq.
current consumption: 7.7 mA.
synth. calibration
SFTX
IDLE
Figure 5-2. Simplified State Diagram with Typical Usage and Current Consumption
5.4
Configuration Software
CC1150 can be configured using the SmartRF Studio [11] software. The SmartRF Studio software is
highly recommended for obtaining optimum register settings, and for evaluating performance and
functionality. A screenshot of the SmartRF Studio user interface for CC1150 is shown in Figure 5-3.
After chip reset, all the registers have default values as shown in the tables in Section 5.20. The optimum
register setting might differ from the default value. After a reset all registers that shall be different from the
default value therefore needs to be programmed through the SPI interface.
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Figure 5-3. SmartRF Studio User Interface
5.5
4-wire Serial Configuration and Data Interface
CC1150 is configured via a simple 4-wire SPI-compatible interface (SI, SO, SCLK and CSn) where
CC1150 is the slave. This interface is also used to read and write buffered data. All address and data
transfer on the SPI interface is done most significant bit first.
All transactions on the SPI interface start with a header byte containing a read/write bit, a burst access bit
and a 6-bit address.
During address and data transfer, the CSn pin (Chip Select, active low) must be kept low. If CSn goes
high during the access, the transfer will be cancelled. The timing for the address and data transfer on the
SPI interface is shown in Figure 5-4 with reference to Table 5-1.
When CSn is pulled low, the MCU must wait until the CC1150 SO pin goes low before starting to transfer
the header byte. This indicates that the voltage regulator has stabilized and the crystal is running. Unless
the chip is in the SLEEP or XOFF states, the SO pin will always go low immediately after taking CSn low.
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tsp
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tch
tcl
tsd
thd
tns
SCLK:
CSn:
Write to register:
SI
SO
X
0
A6
A5
A4
A3
A2
A1
A0
Hi-Z
S7
S6
S5
S4
S3
S2
S1
S0
X
D 6
D 5
D 4
D 3
D 2
D 1
D 0
S7
D 7
S6
S5
S4
S3
S2
S1
S0
D 7
D 6
D 5
D 4
D 3
D 2
D 1
W
W
W
W
W
W
W
X
W
S7
Hi-Z
Read from register:
SI
SO
X
1
A6
A5
A4
A3
A2
A1
A0
Hi-Z
S7
S6
S5
S4
S3
S2
S1
S0
X
R
R
R
R
R
R
D 0
R
R
Hi-Z
Figure 5-4. Configuration Registers Write and Read Operations
Table 5-1. SPI Interface Timing Requirements
PARAMETER
DESCRIPTION
MIN
MAX
100 ns delay inserted between address byte and data byte (single access), or
between address and data, and between each data byte (burst access).
—
10
UNIT
SCLK frequency
fSCLK
SCLK frequency, single access
9
No delay between address and data byte
SCLK frequency, burst access
MHz
6.5
No delay between address and data byte, or between data bytes
tsp,pd
CSn low to positive edge on SCLK, in power-down mode
150
—
µs
tsp
CSn low to positive edge on SCLK, in active mode
20
—
ns
tch
Clock high
50
—
ns
tcl
Clock low
50
—
ns
trise
Clock rise time
—
5
ns
tfall
Clock fall time
—
5
ns
55
—
ns
76
—
ns
tsd
Setup data (negative SCLK edge) to positive edge on
SCLK
Single access
(tsd applies between address and data bytes, and
between data bytes)
Burst access
thd
Hold data after positive edge on SCLK
20
—
ns
tns
Negative edge on SCLK to CSn high
20
—
ns
NOTE
The minimum tsp,pd figure in Table 5-1 can be used in cases where the user does not read
the CHIP_RDYn signal. CSn low to positive edge on SCLK when the chip is woken from
power-down depends on the start-up time of the crystal being used. The 150 μs in Table 5-1
is the crystal oscillator start-up time measured using crystal AT-41CD2 from NDK.
5.5.1
Chip Status Byte
When the header byte, data byte or command strobe is sent on the SPI interface, the chip status byte is
sent by the CC1150 on the SO pin. The status byte contains key status signals, useful for the MCU. The
first bit, s7, is the CHIP_RDYn signal; this signal must go low before the first positive edge of SCLK. The
CHIP_RDYn signal indicates that the crystal is running and the regulated digital supply voltage is stable.
Bit 6, 5 and 4 comprises the STATE value. This value reflects the state of the chip. The XOSC and power
to the digital core is on in the IDLE state, but all other modules are in power down. The frequency and
channel configuration should only be updated when the chip is in this state. The TX state will be active
when the chip is transmitting.
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The last four bits (3:0) in the status byte con-tains FIFO_BYTES_AVAILABLE. This field contains the
number of bytes free for writing into the TX FIFO. When FIFO_BYTES_AVAILABLE=15, 15 or more bytes
are free. Table 5-2 gives a status byte summary.
Table 5-2. Status Byte Summary
BITS
7
NAME
DESCRIPTION
CHIP_RDYn
Stays high until power and crystal have stabilized. Should always be low when using the
SPI interface.
Indicates the current main state machine mode.
The binary number is the value, the result is the state, and the definition is the current
main state machine mode.
(1)
6:04
STATE[2:0]
3:00
FIFO_BYTES_AVAILABLE[3:0]
000 = Idle : IDLE state (1)
001 = Not used : Not used
010 = TX : Transmit mode
011 = FSTXON : Fast TX ready
100 = CALIBRATE : Frequency synthesizer calibration is running
101 = SETTLING : PLL is settling
110 = Not used : Not used
111 = TXFIFO_UNDERFLOW : TX FIFO has underflowed. Acknowledge with SFTX
The number of free bytes in the TX FIFO.
Also reported for some transitional states instead of SETTLING or CALIBRATE, due to a small error.
5.5.2
Register Access
The configuration registers on the CC1150 are located on SPI addresses from 0x00 to 0x2E. Table 5-12
lists all configuration registers. The detailed description of each register is found in Section 5.20.
All configuration registers can be both written and read. The read/write bit controls if the register should be
written or read. When writing to registers, the status byte is sent on the SO pin each time a header byte or
data byte is transmitted on the SI pin. When reading from registers, the status byte is sent on the SO pin
each time a header byte is transmitted on the SI pin.
Registers with consecutive addresses can be accessed in an efficient way by setting the burst bit in the
address header. The address sets the start address in an internal address counter. This counter is
incremented by one each new byte (every 8 clock pulses). The burst access is either a read or a write
access and must be terminated by setting CSn high.
For register addresses in the range 0x30 through 0x3D, the burst bit is used to select between status
registers (burst bit is 1) and command strobes (burst bit is 0). See more in Section 5.5.3. Because of this,
burst access is not available for status registers, so they must be read one at a time. The status registers
can only be read.
5.5.3
SPI Read
When reading register fields over the SPI interface while the register fields are updated by the radio
hardware (for example, MARCSTATE or TXBYTES), there is a small, but finite, probability that a single
read from the register is being corrupt. As an example, the probability of any single read from TXBYTES
being corrupt, assuming the maximum data rate is used, is approximately 80 ppm. Refer to the CC1150
Errata Notes [8] for more details.
5.5.4
Command Strobes
Command Strobes may be viewed as single byte instructions to CC1150. By addressing a Command
Strobe register, internal sequences will be started. These commands are used to disable the crystal
oscillator, enable transmit mode, flush the TX FIFO, and so on. The nine command strobes are listed in
Table 5-11.
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NOTE
An SIDLE strobe will clear all pending command strobes until IDLE state is reached. This
means that if for example an SIDLE strobe is issued while the radio is in TX state, any other
command strobes issued before the radio reaches IDLE state will be ignored.
The command strobe registers are accessed in the same way as for a register write operation, but no data
is transferred. That is, only the R/W bit (set to 0), burst access (set to 0) and the six address bits (in the
range 0x30 through 0x3D) are written.
When writing command strobes, the status byte is sent on the SO pin.
A command strobe may be followed by any other SPI access without pulling CSn high. However, if an
SRES command strobe is being issued, on will have to wait for the SO pin to go low before the next
command strobe can be issued as shown in Figure 5-5.The command strobes are executed immediately,
with the exception of the SPWD and the SXOFF strobes that are executed when CSn goes high.
CSn
SO
SI
SRES
Sxxx
Sxxx
Figure 5-5. SRES Command Strobe
5.5.5
FIFO Access
The 64-byte TX FIFO is accessed through the 0x3F addresses. When the read/write bit is zero, the TX
FIFO is accessed. The TX FIFO is write-only.
The burst bit is used to determine if FIFO access is single byte or a burst access. The single byte access
method expects address with burst bit set to zero and one data byte. After the data byte a new address is
expected; hence, CSn can remain low. The burst access method expects one address byte and then
consecutive data bytes until terminating the access by setting CSn high.
The following header bytes access the FIFO:
• 0x3F: Single byte access to TX FIFO
• 0x7F: Burst access to TX FIFO
When writing to the TX FIFO, the status byte (see Section 5.5.1) is output for each new data byte on SO,
as shown in Figure 5-5. This status byte can be used to detect TX FIFO underflow while writing data to
the TX FIFO.
NOTE
The status byte contains the number of bytes free before writing the byte in progress to the
TX FIFO.
When the last byte that fits in the TX FIFO is transmitted to the SI pin, the status byte received
concurrently on the SO pin will indicate that one byte is free in the TX FIFO.
The TX FIFO may be flushed by issuing a SFTX command strobe. The SFTX command strobe can only
be issues in the IDLE or TX_UNDERFLOW states. The FIFO is cleared when going to the SLEEP state.
Figure 5-6 gives a brief overview of different register access types possible.
16
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CSn:
Command strobe(s):
Read or write register(s):
Read or write consecutive registers (burst):
Read or write n+1 bytes from/to RF FIFO:
Combinations:
ADDRstrobe ADDRstrobe ADDRstrobe ...
ADDRreg
DATA
ADDRreg
DATA
ADDRreg
ADDRreg n
DATAn
DATAn+1
DATAn+2
...
ADDRFIFO DATAbyte 0 DATAbyte 1 DATAbyte 2
ADDRreg
DATA
ADDRstrobe ADDRreg
...
DATA
DATA
...
DATAbyte n-1 DATAbyte n
ADDRstrobe ADDRFIFO DATAbyte 0 DATAbyte 1
...
Figure 5-6. Register Access Types
5.5.6
PATABLE Access
The 0x3E address is used to access the PATABLE, which is used for selecting PA power control settings.
The SPI expects up to eight data bytes after receiving the address. By programming the PATABLE,
controlled PA power ramp-up and ramp-down can be achieved, as well as ASK modulation shaping for
reduced bandwidth.
NOTE
The ASK modulation shaping is limited to output powers below –1 dBm. See SmartRF Studio
[11] for recommended shaping sequence.
See also Section 5.16 for details on output-power programming.
The PATABLE is an 8-byte table that defines the PA control settings to use for each of the eight PA power
values (selected by the 3-bit value FREND0.PA_POWER). The table is written and read from the lowest
setting (0) to the highest (7), one byte at a time. An index counter is used to control the access to the
table. This counter is incremented each time a byte is read or written to the table, and set to the lowest
index when CSn is high. When the highest value is reached the counter restarts at zero.
The access to the PATABLE is either single byte or burst access depending on the burst bit. When using
burst access the index counter will count up; when reaching 7 the counter will restart at 0. The read/write
bit controls whether the access is a write access (R/W=0) or a read access (R/W=1).
If one byte is written to the PATABLE and this value is to be read out then CSn must be set high before
the read access in order to set the index counter back to zero.
NOTE
The content of the PATABLE is lost when entering the SLEEP state. For more information,
see DN501 [8].
5.6
Microcontroller Interface and Pin Configuration
In a typical system, CC1150 will interface to a microcontroller. This microcontroller must be able to do the
following:
• Program CC1150 into different modes
• Write buffered data
• Read back status information via the 4-wire SPI-bus configuration interface (SI, SO, SCLK and CSn)
5.6.1
Configuration Interface
The microcontroller uses four I/O pins for the SPI configuration interface (SI, SO, SCLK and CSn). The
SPI is described in Section 5.5.
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5.6.2
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General Control and Status Pins
The CC1150 has one dedicated configurable pin (GDO0) and one shared pin (GDO1/SO) that can output
internal status information useful for control software. These pins can be used to generate interrupts on
the MCU. See Section 5.17 for more details of the signals that can be programmed. The shared pin is the
SO pin in the SPI interface. The default setting for GDO1/SO is 3-state output. By selecting any other of
the programming options the GDO1/SO pin will become a generic pin. When CSn is low, the pin will
always function as a normal SO pin.
In the synchronous and asynchronous serial modes, the GDO0 pin is used as a serial TX data input pin
while in transmit mode.
The GDO0 pin can also be used for an on-chip analog temperature sensor. By measuring the voltage on
the GDO0 pin with an external ADC, the temperature can be calculated. Specifications for the temperature
sensor are found in Section 4.9. With default PTEST register setting (0x7F), the temperature sensor
output is only available when the frequency synthesizer is enabled (for example, the MANCAL, FSTXON
and TX states). It is necessary to write 0xBF to the PTEST register to use the analog temperature sensor
in the IDLE state. Before leaving the IDLE state, the PTEST register should be restored to its default value
(0x7F).
5.6.3
Optional Radio Control Feature
The CC1150 has an optional way of controlling the radio by reusing SI, SCLK, and CSn from the SPI
interface. This feature allows for a simple three-pin control of the major states of the radio: SLEEP, IDLE,
and TX.
This optional functionality is enabled with the MCSM0.PIN_CTRL_EN configuration bit.
State changes are commanded as follows:
• If CSn is high, the SI and SCLK are set to the desired state according to Table 5-3.
• If CSn goes low, the state of SI and SCLK is latched and a command strobe is generated internally
according to the pin configuration.
It is only possible to change state with the latter functionality. That means that for instance TX will not be
restarted if SI and SCLK are set to TX and CSn toggles. When CSn is low the SI and SCLK has normal
SPI functionality.
All pin control command strobes are executed immediately except the SPWD strobe. The SPWD strobe is
delayed until CSn goes high.
Table 5-3. Optional Pin Control Coding
5.7
CSn
SCLK
SI
FUNCTION
1
X
X
Chip unaffected by SCLK/SI
↓
0
0
Generates SPWD strobe
↓
0
1
Generates STX strobe
↓
1
0
Generates SIDLE strobe
↓
1
1
Defined on the transceiver version (CC1101)
0
SPI mode
SPI mode
SPI mode (wakes up into IDLE if in
SLEEP/XOFF)
Data Rate Programming
The data rate used when transmitting is programmed by the MDMCFG3.DRATE_M and the
MDMCFG4.DRATE_E configuration registers. The data rate is given by the formula below. As Equation 1
shows, the programmed data rate depends on the crystal frequency.
R DATA =
18
(256 + DRATE _ M)´ 2 DRATE _ E
2 28
´ fXOSC
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The following approach shown in Equation 2 can be used to find suitable values for a given data rate.
é
æ R DATA ´ 220 ö ù
÷ú
DRATE _ E = êlog2 ç
ç
÷ú
fXOSC
ê
è
øû
ë
DRATE _ M =
R DATA ´ 228
fXOSC ´ 2DRATE _ E
- 256
(2)
If DRATE_M is rounded to the nearest integer and becomes 256, increment DRATE_E and use
DRATE_M=0.
The data rate can be set from 0.8 kBaud to 500 kBaud with the minimum data rate step size changes
according to Table 5-4.
Table 5-4. Data Rate Step Size
5.8
MIN DATA RATE
[kBaud]
TYPICAL DATA RATE
[kBaud]
MAX DATA RATE
[kBaud]
DATA RATE STEP SIZE
[kBaud]
0.8
1.2 / 2.4
3.17
0.0062
3.17
4.8
6.35
0.0124
6.35
9.6
12.7
0.0248
12.7
19.6
25.4
0.0496
25.4
38.4
50.8
0.0992
50.8
76.8
101.6
0.1984
101.6
153.6
203.1
0.3967
203.1
250
406.3
0.7935
406.3
500
500
1.5869
Packet Handling Hardware Support
The CC1150 has built-in hardware support for packet oriented radio protocols.
In transmit mode, the packet handler can be configured to add the following elements to the packet stored
in the TX FIFO:
• A programmable number of preamble bytes.
• A two byte Synchronization Word. Can be duplicated to give a 4-byte sync word (recommended). It is
not possible to only insert preamble or only insert a sync word.
• Optionally whitening the data with a PN9 sequence.
• Optionally Interleave and Forward Error Code the data.
• Optionally compute and add a 2-byte CRC checksum over the data field.
In a system where CC1150 is used as the transmitter and CC1101 as the receiver the recommended
setting is 4-byte preamble and 4-byte sync word except for 500 kBaud data rate where the recommended
preamble length is 8 bytes.
NOTE
Register fields that control the packet handling features should only be altered when CC1150
is in the IDLE state.
5.8.1
Data Whitening
From a radio perspective, the ideal over the air data are random and DC free. This results in the
smoothest power distribution over the occupied bandwidth. This also gives the regulation loops in the
receiver uniform operation conditions (no data dependencies).
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Real world data often contain long sequences of zeros and ones. Performance can then be improved by
whitening the data before transmitting, and de-whitening in the receiver. With CC1150, in combination with
a CC1101 at the receiver end, this can be done automatically by setting PKTCTRL0WHITE_DATA=1. All
data, except the preamble and the sync word, are then XOR-ed with a 9-bit pseudo-random (PN9)
sequence before being transmitted as shown in Figure 5-7. The PN9 sequence is initialized to all ones. At
the receiver end, the data are XOR-ed with the same pseudo-random sequence. This way, the whitening
is reversed, and the original data appear in the receiver.
Setting PKTCTRL0.WHITE_DATA=1 is recommended for all uses, except when over-the-air compatibility
with other systems is needed.
8
TX_DATA
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
The first TX_DATA byte is shifted in before doing the XOR-operation providing the first TX_OUT[7:0] byte. The
second TX_DATA byte is then shifted in before doing the XOR-operation providing the second TX_OUT[7:0] byte.
TX_OUT[7:0]
Figure 5-7. Data Whitening in TX Mode
5.8.2
Packet Format
The format of the data packet can be configured and consists of the following items:
• Preamble
• Synchronization word
• Optional length byte
• Optional Address byte
• Payload
• Optional 2 byte CRC
Data field
16/32
bits
8
bits
8
bits
8 x n bits
Legend:
Inserted automatically in TX,
processed and removed in RX.
CRC-16
Address field
8 x n bits
Length field
Preamble bits
(1010...1010)
Sync word
Optional data whitening
Optionally FEC encoded/decoded
Optional CRC-16 calculation
Optional user-provided fields processed in TX,
processed but not removed in RX.
Unprocessed user data (apart from FEC
and/or whitening)
16 bits
Figure 5-8. Packet Format
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The preamble pattern is an alternating sequence of ones and zeros (01010101…). The number of
preamble bytes is programmed with the MDMCFG1.NUM_PREAMBLE value. When enabling TX, the
modulator will start transmitting the preamble. When the programmed number of preamble bytes has been
transmitted, the modulator will send the sync word and then data from the TX FIFO if data is available. If
the TX FIFO is empty, the modulator will continue to send preamble bytes until the first byte is written to
the TX FIFO. The modulator will then send the sync word and then the data bytes.
The synchronization word is a two-byte value set in the SYNC1 and SYNC0 registers. The sync word
provides byte synchronization of the incoming packet. A one-byte synch word can be emulated by setting
the SYNC1 value to the preamble pattern. It is also possible to emulate a 32 bit sync word by using
MDMCFG2.SYNC_MODE set to 3 or 7. The sync word will then be repeated twice.
C1150 supports both fixed packet length protocols and variable packet length protocols. Variable or fixed
packet length mode can be used for packets up to 255 bytes. For longer packets, infinite packet length
mode must be used.
Fixed packet length mode is selected by setting PKTCTRL0.LENGTH_CONFIG=0. The desired packet
length is set by the PKTLEN register. In variable packet length mode PKTCTRL0.LENGTH_CONFIG=1,
the packet length is configured by the first byte after the sync word. The packet length is defined as the
payload data, excluding the length byte and the optional automatic CRC.
With PKTCTRL0.LENGTH_CONFIG=2, the packet length is set to infinite and transmission will continue
until turned off manually. The infinite mode can be turned off while a packet is being transmitted. As
described in Section 5.8.2.1, this can be used to support packet formats with different length configuration
than natively supported by CC1150. One should make sure that TX mode is not turned off during the
transmission of the first half of any byte. Refer to the CC1150 Errata Notes [8] for more details.
NOTE
The minimum packet length supported (excluding the optional length byte and CRC) is one
byte of payload data.
5.8.2.1
Arbitrary Length Field Configuration
The packet automation control register, PKTCTRL0, can be reprogrammed during TX. This opens the
possibility to transmit packets that are longer than 256 bytes and still be able to use the packet handling
hardware support. At the start of the packet, the infinite mode (PKTCTRL0.LENGTH_CONFIG=2) must be
active. The PKTLEN register is set to mod(length, 256). When less than 256 bytes remains of the packet,
the MCU disables infinite packet length and activates fixed length packets. When the internal byte counter
reaches the PKTLEN value, the transmission ends (the radio enters the state determined by
TXOFF_MODE). Automatic CRC appending can be used (by setting PKTCTRL0.CRC_EN=1).
When, for example, a 600-byte packet is to be transmitted, the MCU should do the following (see also
Figure 5-9):
• Set PKTCTRL0.LENGTH_CONFIG=2.
• Pre-program the PKTLEN register to mod(600,256)=88.
• Transmit at least 345 bytes, for example by filling the 64-byte TX FIFO six times (384 bytes
transmitted).
• Set PKTCTRL0.LENGTH_CONFIG=0.
• The transmission ends when the packet counter reaches 88. A total of 600 bytes are transmitted.
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Internal byte counter in packet handler counts from 0 to 255 and then starts at 0 again
0,1,..........,88,....................255,0,........,88,..................,255,0,........,88,..................,255,0,.......................
Infinite packet length enabled
Fixed packet length
enabled when less than
256 bytes remains of
packet
600 bytes transmitted
Length field transmitted. Tx PKTLEN value set to mod(600,256) = 88
Figure 5-9. Arbitrary Length Field Configuration
5.8.3
Packet Handling in Transmit Mode
The payload that is to be transmitted must be written into the TX FIFO. The first byte written must be the
length byte when variable packet length is enabled. The length byte has a value equal to the payload of
the packet (including the optional address byte). If fixed packet length is enabled, then the first byte written
to the TX FIFO is interpreted as the destination address, if this feature is enabled in the device that
receives the packet.
The modulator will first send the programmed number of preamble bytes. If data is available in the TX
FIFO, the modulator will send the two-byte (optionally 4-byte) sync word and then the payload in the TX
FIFO. If CRC is enabled, the checksum is calculated over all the data pulled from the TX FIFO and the
result is sent as two extra bytes at the end of the payload data. If the TX FIFO runs empty before the
complete packet has been transmitted, the radio will enter TXFIFO_UNDERFLOW state. The only way to
exit this state is by issuing an SFTX strobe. Writing to the TX FIFO after it has underflowed will not restart
TX mode.
If whitening is enabled, the length byte, payload data and the two CRC bytes will be whitened. This is
done before the optional FEC/Interleaver stage. Whitening is enabled by setting
PKTCTRL0.WHITE_DATA=1.
If FEC/Interleaving is enabled, the length byte, payload data and the two CRC bytes will be scrambled by
the interleaver, and FEC encoded before being modulated. FEC is enabled by setting
MDMCFG1.FEC_EN=1.
5.8.4
Packet Handling in Firmware
When implementing a packet oriented radio protocol in firmware, the MCU needs to know when a packet
has been transmitted. Additionally, for packets longer than 64 bytes, the TX FIFO needs to be refilled
while in TX. This means that the MCU needs to know the number of bytes that can be written to the TX
FIFO. There are two possible solutions to get the necessary status information:
a. Interrupt Driven Solution
– The GDO pins can be used in TX to give an interrupt when a sync word has been transmitted or
when a complete packet has been transmitted by setting IOCFGx.GDOx_CFG=0x06. In addition,
there are two configurations for the IOCFGx.GDOx_CFG register that can be used as an interrupt
source to provide information on how many bytes that is in the TX FIFO. The
IOCFGx.GDOx_CFG=0x02 and the IOCFGx.GDOx_CFG=0x03 configurations are associated with
the TX FIFO. See Table 5-10 for more information.
b. SPI Polling
– The PKTSTATUS register can be polled at a given rate to get information about the current GDO2
and GDO0 values respectively. The TXBYTES register can be polled at a given rate to get
information about the number of bytes in the TX FIFO. Alternatively, the number of bytes in the TX
FIFO can be read from the chip status byte returned on the MISO line each time a header byte,
data byte, or command strobe is sent on the SPI bus.
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– It is recommended to employ an interrupt driven solution due to that when using SPI polling, there
is a small, but finite, probability that a single read from registers PKTSTATUS and TXBYTES is
being corrupt. The same is the case when reading the chip status byte. This is explained in the
CC1150 Errata Notes [8] Refer to the TI website for SW examples [12].
5.9
Modulation Formats
CC1150 supports amplitude, frequency and phase shift modulation formats. The desired modulation
format is set in the MDMCFG2.MOD_FORMAT register.
Optionally, the data stream can be Manchester coded by the modulator. This option is enabled by setting
MDMCFG2.MANCHESTER_EN=1. Manchester encoding cuts the effective data rate in half, and thus
Manchester is not supported for 500 kBaud. Further note that Manchester encoding is not supported at
the same time as using the FEC/Interleaver option or when using MSK modulation.
5.9.1
Frequency Shift Keying
CC1150 has the possibility to use Gaussian shaped 2_FSK (GFSK). The 2-FSK signal is then shaped by
a Gaussian filter with BT=1, producing a GFSK modulated signal. This spectrum-shaping feature improves
adjacent channel power (ACP) and occupied bandwidth.
In “true” 2-FSK systems with abrupt frequency shifting, the spectrum is inherently broad. By making the
frequency shift “softer”, the spectrum can be made significantly narrower. Thus, higher data rates can be
transmitted in the same bandwidth using GFSK.
The frequency deviation is programmed with the DEVIATION_M and DEVIATION_E values in the
DEVIATN register. The value has an exponent/mantissa form, and the resultant deviation is given by
Equation 3.
f
fdev = xosc
´ (8 + DEVIATION _ M) ´ 2DEVIATION _ E
17
2
(3)
The symbol encoding is shown in Table 5-5.
Table 5-5. Symbol Encoding for 2-FSK/GFSK
Modulation
FORMAT
SYMBOL
CODING
0
– Deviation
1
+ Deviation
2-FSK/GFSK
5.9.2
Minimum Shift Keying
When using MSK [(Identical to offset QPSK with half-sine shaping (data coding may differ)], the complete
transmission (preamble, sync word, and payload) will be MSK modulated.
Phase shifts are performed with a constant transition time. The fraction of a symbol period used to change
the phase can be modified with the DEVIATN.DEVIATION_M setting. This is equivalent to changing the
shaping of the symbol.
NOTE
When
using
MSK,
Manchester
MDMCFG2.MANCHESTER_EN=0.
encoding
must
be
disabled
by
setting
The MSK modulation format implemented in CC1150 inverts the data compared to,
for example, signal generators.
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5.9.3
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Amplitude Modulation
CC1150 supports two different forms of amplitude modulation: On-Off Keying (OOK) and Amplitude Shift
Keying (ASK).
OOK modulation simply turns on or off the PA to modulate 1 and 0 respectively.
The ASK variant supported by the CC1150 allows programming of the modulation depth (the difference
between 1 and 0), and shaping of the pulse amplitude. Pulse shaping will produce a more bandwidth
constrained output spectrum.
NOTE
The OOK/ASK pulse shaping feature on the CC1150 does only support output power up to
about –1 dBm. The DEVIATN register has no effect when using ASK/OOK.
5.10 Forward Error Correction with Interleaving
5.10.1 Forward Error Correction (FEC)
CC1150 has built in support for Forward Error Correction (FEC) that can be used with CC1101 at the
receiver end. To enable this option, set MDMCFG1.FEC_EN to 1. FEC is only supported in fixed packet
length mode, that is, when PKTCTRL0.LENGTH_CONFIG=0. FEC is employed on the data field and CRC
word in order to reduce the gross bit error rate when operating near the sensitivity limit. Redundancy is
added to the transmitted data in such a way that the receiver can restore the original data in the presence
of some bit errors.
The use of FEC allows correct reception at a lower Signal-to-Noise RATIO (SNR), thus extending
communication range. Alternatively, for a given SNR, using FEC decreases the bit error rate (BER). As
the packet error rate (PER) is related to BER by Equation 4.
PER = 1 – (1 – BER)packet_length
(4)
A lower BER can be used to allow longer packets, or a higher percentage of packets of a given length, to
be transmitted successfully.
Finally, in realistic ISM radio environments, transient and time-varying phenomena will produce occasional
errors even in otherwise good reception conditions. FEC will mask such errors and, combined with
interleaving of the coded data, even correct relatively long periods of faulty reception (burst errors).
The FEC scheme adopted for CC1150 is convolutional coding, in which n bits are generated based on k
input bits and the m most recent input bits, forming a code stream able to withstand a certain number of
bit errors between each coding state (the m-bit window).
The convolutional coder is a rate 1/2 code with a constraint length of m = 4. The coder codes one input bit
and produces two output bits; hence, the effective data rate is halved. This means that in order to transmit
at the same effective data rate when using FEC, it is necessary to use twice as high over-the-air data rate.
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5.10.2 Interleaving
Data received through real radio channels will often experience burst errors due to interference and timevarying signal strengths. In order to increase the robustness to errors spanning multiple bits, interleaving
is used when FEC is enabled. After de-interleaving, a continuous span of errors in the received stream will
become single errors spread apart.
CC1150 employs matrix interleaving, which is illustrated in Figure 5-10. The on-chip interleaving buffer is
a 4 × 4 matrix. In the transmitter, the data bits are written into the rows of the matrix, whereas the bit
sequence to be transmitted is read from the columns of the matrix and fed to the rate ½ convolutional
coder. Conversely, in a CC1101 receiver, the received symbols are written into the rows of the matrix,
whereas the data passed onto the convolutional decoder is read from the columns of the matrix.
When FEC and interleaving is used, at least one extra byte is required for trellis termination. In addition,
the amount of data transmitted over the air must be a multiple of the size of the interleaver buffer (two
bytes). The packet control hardware therefore automatically inserts one or two extra bytes at the end of
the packet, so that the total length of the data to be interleaved is an even number. Note that these extra
bytes are invisible to the user, as they are removed before the received packet enters the RX FIFO in a
CC1101.
When FEC and interleaving is used, the minimum data payload is 2 bytes in fixed and variable packet
length mode.
Interleaver
Write buffer
Packet
Engine
Interleaver
Read buffer
FEC
Encoder
Modulator
Interleaver
Write buffer
Interleaver
Read buffer
FEC
Decoder
Demodulator
Packet
Engine
Figure 5-10. : General Principle of Matrix Interleaving
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5.11 Radio Control
SIDLE
SLEEP
0
SPWD
CAL_COMPLETE
CSn = 0
IDLE
1
MANCAL
3,4,5
SXOFF
SCAL
CSn = 0
XOFF
2
STX | SFSTXON
FS_WAKEUP
6,7
FS_AUTOCAL = 01
&
STX | SFSTXON
FS_AUTOCAL = 00 | 10 | 11
&
STX | SFSTXON
SFSTXON
FSTXON
18
SETTLING
9,10
CALIBRATE
8
CAL_COMPLETE
STX
STX
TXOFF_MODE = 01
TX
19,20
TXOFF_MODE = 10
TXFIFO_UNDERFLOW
TXOFF_MODE = 00
&
FS_AUTOCAL = 10 | 11
CALIBRATE
12
TXOFF_MODE = 00
&
FS_AUTOCAL = 00 | 01
TX_UNDERFLOW
22
SFTX
IDLE
1
Figure 5-11. Radio Control State Diagram
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CC1150 has a built-in state machine that is used to switch between different operations states (modes).
The change of state is done either by using command strobes or by internal events such as TX FIFO
underflow.
A simplified state diagram, together with typical usage and current consumption, is shown in Figure 5-2.
The complete radio control state diagram is shown in Figure 5-11. The numbers refer to the state number
readable in the MARCSTATE status register. This functionality is primarily for test purposes.
5.11.1 Power On Start-up Sequence
When the power supply is turned on, the system must be reset. This is achieved by one of the two
sequences described in Section 5.11.1.1 or Section 5.11.1.2, that is, automatic power-on reset or manual
reset. After the automatic power-on reset or manual reset it is also recommended to change the signal
that is output on the GDO0 pin. The default setting is to output a clock signal with a frequency of
CLK_XOSC/192, but to optimize performance in TX, an alternative GDO setting should be selected from
the settings found in Table 5-10.
5.11.1.1 Automatic POR
A power-on reset circuit is included in the CC1150. The minimum requirements stated in Section 4.7 must
be followed for the power-on reset to function properly. The internal power-up sequence is completed
when CHIP_RDYn goes low. CHIP_RDYn is observed on the SO pin after CSn is pulled low. See Section
10.1 for more details on CHIP_RDYn.
When the CC1150 reset is completed the chip will be in the IDLE state and the crystal oscillator running. If
the chip has had sufficient time for the crystal oscillator and voltage regulator to stabilize after the poweron-reset, the SO pin will go low immediately after taking CSn low. If CSn is taken low before reset is
completed the SO pin will first go high, indicating that the crystal oscillator and voltage regulator is not
stabilized, before going low as shown in Figure 5-12.
CSn
SO
XOSC Stable
Figure 5-12. Power-on Reset
5.11.1.2 Manual Reset
The other global reset possibility on CC1150 is the SRES command strobe. By issuing this strobe, all
internal registers and states are set to the default, IDLE state. The power-up sequence is as follows (see
Figure 5-13):
• Set SCLK = 1 and SI = 0.
• Strobe CSn low / high. Make sure to hold CSn high for at least 40 µs relative to pulling CSn low.
• Pull CSn low and wait for SO to go low (CHIP_RDYn).
• Issue the SRES strobe on the SI line.
• When SO goes low again, reset is complete and the chip is in the IDLE state.
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XOSC and voltage regulator switched on
40 µs
CSn
SO
XOSC Stable
SI
SRES
Figure 5-13. Power-up with SRES
NOTE
The above reset procedure is only required just after the power supply is first turned on. If
the user wants to reset the CC1150 after this, it is only necessary to issue an SRES
command strobe.
It is recommended to always send a SRES command strobe on the SPI interface after power-on even
though power-on reset is used.
5.11.2 Crystal Control
The crystal oscillator is automatically turned on when CSn goes low. It will be turned off if the SXOFF or
SPWD command strobes are issued; the state machine then goes to XOFF or SLEEP respectively. This
can only be done from IDLE state. The XOSC will be turned off when CSn is released (goes high). The
XOSC will be automatically turned on again when CSn goes low. The state machine will then go to the
IDLE state. The SO pin on the SPI interface must be pulled low before the SPI interface is ready to be
used; as described in Section 5.5.1.
Crystal oscillator start-up time depends on crystal ESR and load capacitances. The electrical specification
for the crystal oscillator can be found in Section 4.7.
5.11.3 Voltage Regulator Control
The voltage regulator to the digital core is controlled by the radio controller. When the chip enters the
SLEEP state, which is the state with the lowest current consumption, the voltage regulator is disabled.
This occurs after CSn is released when a SPWD command strobe has been sent on the SPI interface.
The chip is then in the SLEEP state. Setting CSn low again will turn on the regulator and crystal oscillator
and make the chip enter the IDLE state.
On the CC1150, all register values (with the exception of the MCSM0.PO_TIMEOUT field) are lost in the
SLEEP state. After the chip gets back to the IDLE state, the registers will have default (reset) contents
and must be reprogrammed over the SPI interface.
5.11.4 Active Mode
The active transmit mode is activated by the MCU by using the STX command strobe.
The frequency synthesizer must be calibrated regularly. CC1150 has one manual calibration option (using
the SCAL strobe), and three automatic calibration options, controlled by the MCSM0.FS_AUTOCAL
setting:
• Calibrate when going from IDLE to TX (or FSTXON)
• Calibrate when going from TX to IDLE
• Calibrate every fourth time when going from TX to IDLE
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The calibration takes a constant number of XOSC cycles; see Table 5-6 for timing details. When TX is
active, the chip will remain in the TX state until the current packet has been successfully transmitted. Then
the state will change as indicated by the MCSM1.TXOFF_MODE setting. The possible destinations are:
• IDLE
• FSTXON: Frequency synthesizer on and ready at the TX frequency. Activate TX with STX.
• TX: Start sending preambles
The SIDLE command strobe can always be used to force the radio controller to go to the IDLE state. Note
that if the radio goes from TX to IDLE by issuing an SIDLE strobe, the automatic calibration-when-goingfrom-TX-to-IDLE will not be performed.
5.11.5 Timing
The radio controller controls most timing in CC1150, such as synthesizer calibration and PLL lock.
Table 5-6 shows timing in crystal clock cycles for key state transitions. Timing from IDLE to TX is
constant, dependent on the auto calibration setting. The calibration time is constant 18739 clock periods.
Power on time and XOSC start-up times are variable, but within the limits stated in Section 4.7.
NOTE
In a frequency hopping spread spectrum or a multi-channel protocol, the calibration time can
be reduced from 721 µs to approximately 150 µs. This is explained in Section 5.19.2.
Table 5-6. State Transition Timing
DESCRIPTION
Idle to TX/FSTXON, no calibration
Idle to TX/FSTXON, with calibration
TX to IDLE, no calibration
XOSC PERIODS
26 MHz CRYSTAL
2298
88.4 µs
≈ 21037
809 µs
2
0.1 µs
TX to IDLE, including calibration
≈ 18739
721 µs
Manual calibration
≈ 18739
721 µs
5.12 Data FIFO
The CC1150 contains a 64 byte FIFO for data to be transmitted. The SPI interface is used for writing to
the TX FIFO. Section 10.5 contains details on the SPI FIFO access. The FIFO controller will detect
underflow in the TX FIFO.
When writing to the TX FIFO, it is the responsibility of the MCU to avoid TX FIFO overflow. This will not be
detected by the CC1150. A TX FIFO overflow will result in an error in the TX FIFO content.
Table 5-7. FIFO_THR Settings
and the Corresponding FIFO
Thresholds
FIFO_THR
BYTES in TX
FIFO
0000
61
0001
57
0010
53
0011
49
0100
45
0101
41
0110
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Table 5-7. FIFO_THR Settings
and the Corresponding FIFO
Thresholds (continued)
FIFO_THR
BYTES in TX
FIFO
0111
33
1000
29
1001
25
1010
21
1011
17
1100
13
1101
9
1110
5
1111
1
The chip status byte that is available on the SO pin while transferring the SPI address contains the fill
grade of the TX FIFO. Section 5.5.1 contains more details on this.
The number of bytes in the TX FIFO can also be read from the TXBYTES.NUM_TXBYTES status register.
The 4-bit FIFOTHR.FIFO_THR setting is used to program the FIFO threshold point. Table 5-7 lists the 16
FIFO_THR settings and the corresponding thresholds for the TX FIFO.
FIFO_THR=13
Underflow
margin
8 bytes
TXFIFO
Figure 5-14. Example of FIFO at Threshold
A flag will assert when the number of bytes in the FIFO is equal to or higher than the programmed
threshold. The flag is used to generate the FIFO status signals that can be viewed on the GDO pins (see
Section 5.17).
Figure 5-15 shows the number of bytes in the TX FIFO when the threshold flag toggles, in the case of
FIFO_THR=13. Figure 5-15 shows the flag as the FIFO is filled above the threshold, and then drained
below.
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NUM_TXBYTES
6
7
8
9 10 9
8
7
6
GDO
Figure 5-15. FIFO_THR=13 versus Number of Bytes in FIFO
5.13 Frequency Programming
The frequency programming in CC1150 is designed to minimize the programming needed in a channeloriented system.
To set up a system with channel numbers, the desired channel spacing is programmed with the
MDMCFG0.CHANSPC_M and MDMCFG1.CHANSPC_E registers. The channel spacing registers are
mantissa and exponent respectively.
The base or start frequency is set by the 24-bit frequency word located in the FREQ2, FREQ1 and
FREQ0 registers. This word will typically be set to the centre of the lowest channel frequency that is to be
used.
The desired channel number is programmed with the 8-bit channel number register, CHANNR.CHAN,
which is multiplied by the channel offset. The resultant carrier frequency is given by Equation 5.
f
´ FREQ + CHAN ´ (256 + CHANSPC _ M)´ 2CHANSPC _ E -2
fcarrier = XOSC
16
2
(5)
(
(
))
With a 26-MHz crystal, the maximum channel spacing is 405 kHz. To get, for example, 1-MHz channel
spacing on solution is to use 333-kHz channel spacing and select each third channel in CHANNR.CHAN.
If any frequency programming register is altered when the frequency synthesizer is running, the
synthesizer may give an undesired response. Hence, the frequency programming should only be updated
when the radio is in the IDLE state.
5.14 VCO
The VCO is completely integrated on-chip.
5.14.1 VCO and PLL Self-Calibration
The VCO characteristics will vary with temperature and supply voltage changes, as well as the desired
operating frequency. In order to ensure reliable operation, CC1150 includes frequency synthesizer selfcalibration circuitry. This calibration should be done regularly, and must be performed after turning on
power and before using a new frequency (or channel). The number of XOSC cycles for completing the
PLL calibration is given in Table 5-6.
The calibration can be initiated automatically or manually. The synthesizer can be automatically calibrated
each time the synthesizer is turned on, or each time the synthesizer is turned off. This is configured with
the MCSM0.FS_AUTOCAL register setting.
In manual mode, the calibration is initiated when the SCAL command strobe is activated in the IDLE
mode.
The calibration values are not maintained in sleep mode. Therefore, the CC1150 must be recalibrated
after reprogramming the configuration registers when the chip has been in the SLEEP state.
To check that the PLL is in lock the user can program register IOCFGx.GDOx_CFG to 0x0A and use the
lock detector output available on the GDOx pin as an interrupt for the MCU (x = 0, 1, or 2). A positive
transition on the GDOx pin means that the PLL is in lock. As an alternative the user can read register
FSCAL1. The PLL is in lock if the register content is different from 0x3F. See more information in the
CC1150 Errata Notes [8].
For more robust operation the source code could include a check so that the PLL is re-calibrated until PLL
lock is achieved if the PLL does not lock the first time.
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5.15 Voltage Regulators
CC1150 contains several on-chip linear voltage regulators, which generate the supply voltage needed by
low-voltage modules. These voltage regulators are invisible to the user, and can be viewed as integral
parts of the various modules. The user must however make sure that the absolute maximum ratings and
required pin voltages in Section 4.1 and Table 3-1 are not exceeded.
Setting the CSn pin low turns on the voltage regulator to the digital core and start the crystal oscillator.
The SO pin on the SPI interface must go low before the first positive edge on the SCLK (setup time is s
given in Table 5-1).
If the chip is programmed to enter power-down mode (SPWD strobe issued), the power will be turned off
after CSn goes high. The power and crystal oscillator will be turned on again when CSn goes low.
The voltage regulator for the digital core requires one external decoupling capacitor. The voltage regulator
output should only be used for driving the CC1150.
5.16 Output Power Programming
The RF output power level from the device has two levels of programmability, as illustrated in Figure 5-16.
Firstly, the special PATABLE register can hold up to eight user selected output power settings. Secondly,
the 3-bit FREND0.PA_POWER value selects the PATABLE entry to use. This two-level functionality
provides flexible PA power ramp up and ramp down at the start and end of transmission, as well as ASK
modulation shaping. In each case, all the PA power settings in the PATABLE from index 0 up to the
FREND0.PA_POWER value are used.
The power ramping at the start and at the end of a packet can be turned off by setting
FREND0.PA_POWER to zero and then programming the desired output power to index 0 in the
PATABLE.
If OOK modulation is used, the logic 0 and logic 1 power levels shall be programmed to index 0 and 1
respectively.
Table 5-8 contains recommended PATABLE settings for various output levels and frequency bands.
DN012 [3] gives complete tables for the different frequency bands. Using PA settings from 0x61 to 0x6F is
not recommended. Table 5-9 contains output power and current consumption for default PATABLE setting
(0xC6).
PATABLE must be programmed in burst mode if you want to write to other entries than PATABLE[0]. See
Section 5.5.6 for PATABLE programming details.
PATABLE(7)[7:0]
PATABLE(6)[7:0]
The PA uses this
setting.
PATABLE(5)[7:0]
PATABLE(4)[7:0]
PATABLE(3)[7:0]
PATABLE(2)[7:0]
PATABLE(1)[7:0]
Settings 0 to PA_POWER are
used during ramp-up at start of
transmission and ramp-down at
end of transmission, and for
ASK/OOK modulation.
PATABLE(0)[7:0]
Index into PATABLE(7:0)
e.g 6
PA_POWER[2:0]
in FREND0 register
TM
The SmartRF
Studio software
should be used to obtain optimum
PATABLE settings for various
output powers.
Figure 5-16. PA_POWER and PATABLE
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Table 5-8. Optimum PATABLE Settings for Various Output Power Levels and Frequency Bands
OUTPUT
POWER
[dBm]
315 MHz
SETTING
433 MHz
CURRENT
CONSUMPTION,
TYP. [mA]
868 MHz
SETTING
CURRENT
CONSUMPTION,
TYP. [mA]
915 MHz
SETTING
CURRENT
CONSUMPTION,
TYP. [mA]
SETTING
CURRENT
CONSUMPTION,
TYP. [mA]
–30
0x12
9.9
0x03
10.8
0x03
11.2
0x03
11.1
–20
0x0E
10.4
0x0E
11.4
0x0C
11.7
0x0F
11.7
–10
0x26
12.5
0x26
13.3
0x26
13.7
0x34
13.6
–5
0x57
12.2
0x57
12.9
0x57
13.3
0x56
13.3
0
0x60
14.1
0x60
14.6
0x60
15.5
0x50
15.2
3
0x8B
15.8
0x8A
16.5
0x8A
17.4
0x89
17.4
7
0xCC
21.4
0xC8
23
0xCC
24.4
0xC8
24.6
10
0xC4
25.6
0xC2
26.1
0xC3
29.3
0xC0
29.3
Table 5-9. Output Power and Current Consumption for Default PATABLE Setting
DEFAULT
POWER
SETTING
0xC6
315 MHz
433 MHz
868 MHz
915 MHz
OUTPUT
POWER
[dBm]
CURRENT
CONSUMPTION,
TYP. [mA]
OUTPUT
POWER
[dBm]
CURRENT
CONSUMPTION,
TYP. [mA]
OUTPUT
POWER
[dBm]
CURRENT
CONSUMPTION,
TYP. [mA]
OUTPUT
POWER
[dBm]
CURRENT
CONSUMPTION,
TYP. [mA]
9.3
24.4
8.1
23.9
8.9
27.3
7.7
25.5
5.16.1 Shaping and PA Ramping
With ASK modulation, up to eight power settings are used for shaping. The modulator contains a counter
that counts up when transmitting a one and down when transmitting a zero. The counter counts at a rate
equal to 8 times the symbol rate. The counter saturates at FREND0.PA_POWER and 0 respectively. This
counter value is used as an index for a lookup in the power table. Thus, in order to utilize the whole table,
FREND0.PA_POWER should be 7 when ASK is active. The shaping of the ASK signal is dependent on
the configuration of the PATABLE. Figure 5-17 shows some examples of ASK shaping.
NOTE
The OOK/ASK pulse shaping feature on the CC1150 is only supported for output power
levels below –1 dBm.
Output Power
PATABLE[7]
PATABLE[6]
PATABLE[5]
PATABLE[4]
PATABLE[3]
PATABLE[2]
PATABLE[1]
PATABLE[0]
1
0
0
1
0
1
1
0
Time
Bit Sequence
FREND0.PA_POWER = 3
FREND0.PA_POWER = 7
Figure 5-17. Shaping of ASK Signal
5.17 General Purpose and Test Output Control Pins
The two digital output pins GDO0 and GDO1 are general control pins. Their functions are programmed by
IOCFG0.GDO0_CFG and IOCFG1.GDO1_CFG respectively. Table 5-10 shows the different signals that
can be monitored on the GDO pins. These signals can be used as an interrupt to the MCU.
GDO1 is the same pin as the SO pin on the SPI interface, thus the output programmed on this pin will
only be valid when CSn is high. The default value for GDO1 is 3-stated, which is useful when the SPI
interface is shared with other devices.
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The default value for GDO0 is a 125 to 146 kHz clock output (XOSC frequency divided by 192). Because
the XOSC is turned on at power-on-reset, this can be used to clock the MCU in systems with only one
crystal. When the MCU is up and running it can change the clock frequency by writing to
IOCFG0.GDO0_CFG.
An on-chip analog temperature sensor is enabled by writing the value 128 (0x80h) to the
IOCFG0.GDO0_CFG register. The voltage on the GDO0 pin is then proportional to temperature. See
Section 4.9 for temperature sensor specifications.
Table 5-10. GDO signal selection(x = 0 or 1)
GDOx_CFG[5:0]
Reserved – defined on the transceiver version (CC1101).
1 (0x01)
Reserved – defined on the transceiver version (CC1101).
2 (0x02)
Associated to the TX FIFO: Asserts when the TX FIFO is filled at or above the TX FIFO threshold. De-asserts
when the TX FIFO is below the same threshold.
3 (0x03)
Associated to the TX FIFO: Asserts when TX FIFO is full. De-asserts when the TX FIFO is drained below the
TX FIFO threshold.
4 (0x04)
Reserved – defined on the transceiver version (CC1101).
5 (0x05)
Asserts when the TX FIFO has underflowed. De-asserts when the FIFO is flushed.
6 (0x06)
Asserts when sync word has been sent, and de-asserts at the end of the packet. In TX the pin will also deassert if the TX FIFO underflows.
7 (0x07)
Reserved – defined on the transceiver version (CC1101).
8 (0x08)
Reserved – defined on the transceiver version (CC1101).
9 (0x09)
Reserved – defined on the transceiver version (CC1101).
10 (0x0A)
11 (0x0B)
34
DESCRIPTION
0 (0x00)
Lock detector output. The PLL is in lock if the lock detector output has a positive transition or is constantly
logic high. To check for PLL lock the lock detector output should be used as an interrupt for the MCU.
Serial Clock. Synchronous to the data in synchronous serial mode.
In TX mode, data is sampled by CC1150 on the rising edge of the serial clock when GDOx_INV=0.
12 (0x0C)
Reserved – defined on the transceiver version (CC1101).
13 (0x0D)
Reserved – defined on the transceiver version (CC1101).
14 (0x0E)
Reserved – defined on the transceiver version (CC1101).
15 (0x0F)
Reserved – defined on the transceiver version (CC1101).
16 (0x10)
Reserved – used for test.
17 (0x11)
Reserved – used for test.
18 (0x12)
Reserved – used for test.
19 (0x13)
Reserved – used for test.
20 (0x14)
Reserved – used for test.
21 (0x15)
Reserved – used for test.
22 (0x16)
Reserved – defined on the transceiver version (CC1101).
23 (0x17)
Reserved – defined on the transceiver version (CC1101).
24 (0x18)
Reserved – used for test.
25 (0x19)
Reserved – used for test.
26 (0x1A)
Reserved – used for test.
27 (0x1B)
PA_PD. PA is enabled when 1, in power-down when 0.
28 (0x1C)
Reserved – defined on the transceiver version (CC1101).
29 (0x1D)
Reserved – defined on the transceiver version (CC1101).
30 (0x1E)
Reserved – used for test.
31 (0x1F)
Reserved – used for test.
32 (0x20)
Reserved – used for test.
33 (0x21)
Reserved – used for test.
34 (0x22)
Reserved – used for test.
35 (0x23)
Reserved – used for test.
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Table 5-10. GDO signal selection(x = 0 or 1) (continued)
GDOx_CFG[5:0]
(1)
(2)
DESCRIPTION
36 (0x24)
Reserved – defined on the transceiver version (CC1101).
37 (0x25)
Reserved – defined on the transceiver version (CC1101).
38 (0x26)
Reserved – used for test.
39 (0x27)
Reserved – defined on the transceiver version (CC1101).
40 (0x28)
Reserved – used for test.
41 (0x29)
CHIP_RDYn
42 (0x2A)
Reserved – used for test.
43 (0x2B)
XOSC_STABLE
44 (0x2C)
Reserved – used for test.
45 (0x2D)
GDO0_Z_EN_N. When this output is 0, GDO0 is configured as input (for serial TX data).
46 (0x2E)
High impedance (3-state)
47 (0x2F)
HW to 0 (HW1 achieved by setting GDOx_INV=1)
48 (0x30)
CLK_XOSC/1
49 (0x31)
CLK_XOSC/1.5
50 (0x32)
CLK_XOSC/2
51 (0x33)
CLK_XOSC/3
52 (0x34)
CLK_XOSC/4
53 (0x35)
CLK_XOSC/6
54 (0x36)
CLK_XOSC/8
55 (0x37)
CLK_XOSC/12
56 (0x38)
CLK_XOSC/16
57 (0x39)
CLK_XOSC/24
58 (0x3A)
CLK_XOSC/32
59 (0x3B)
CLK_XOSC/48
60 (0x3C)
CLK_XOSC/64
61 (0x3D)
CLK_XOSC/96
62 (0x3E)
CLK_XOSC/128
63 (0x3F)
CLK_XOSC/192
See
(1) (2)
There are 2 GDO pins, but only one CLK_XOSC/n can be selected as an output at any time. If CLK_XOSC/n is to be monitored on one
of the GDO pins, the other GDO pin must be configured to values less than 0x30. The GDO0 default value is CLK_XOSC/192.
To optimize RF performance, these signals should not be used while the radio is in TX mode.
5.18 Asynchronous and Synchronous Serial Operation
Several features and modes of operation have been included in the CC1150 to provide backward
compatibility with previous TI products and other existing RF communication systems. For new systems, it
is recommended to use the built-in packet handling features, as they can give more robust
communication, significantly offload the microcontroller and simplify software development.
5.18.1 Asynchronous Serial Operation
For backward compatibility with systems already using the asynchronous data transfer from other TI
products, asynchronous transfer is also included in CC1150.
When asynchronous transfer is enabled, several of the support mechanisms for the MCU that are included
in CC1150 will be disabled, such as packet handling hardware, buffering in the FIFO and so on. The
asynchronous transfer mode does not allow the use of the data whitener, interleaver and FEC, and it is
not possible to use Manchester encoding. MSK is not supported for asynchronous transfer.
Setting PKTCTRL0.PKT_FORMAT to 3 enables asynchronous transparent (serial) mode. In TX, the
GDO0 pin is used for data input (TX data).
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The MCU must control start and stop of transmit with the STX and SIDLE strobes.
The CC1150 modulator samples the level of the asynchronous input 8 times faster than the programmed
data rate. The timing requirement for the asynchronous stream is that the error in the bit period must be
less than one eighth of the programmed data rate.
5.18.2 Synchronous Serial Operation
Setting PKTCTRL0.PKT_FORMAT to 1 enables synchronous serial operation mode. In this operational
mode the data must be NRZ encoded (MDMCFG2.MANCHESTER_EN=0). In synchronous serial
operation mode, data is transferred on a two wire serial interface. The CC1150 provides a clock that is
used to set up new data on the data input line. Data input (TX data) is the GDO0 pin. This pin will
automatically be configured as an input when TX is active. The TX latency is 8 bits.
Preamble and sync word insertion may or may not be active, dependent on the sync mode set by the
MDMCFG3.SYNC_MODE.
If preamble and sync word is disabled, all other packet handler features and FEC should also be disabled.
The MCU must then handle preamble and sync word insertion in software.
If preamble and sync word insertion is left on, all packet handling features and FEC can be used. When
using the packet handling features synchronous serial mode, the CC1150 will insert the preamble and
sync word and the MCU will only provide the data payload. This is equivalent to the recommended FIFO
operation mode.
5.19 System Considerations and Guidelines
5.19.1 SRD Regulations
International regulations and national laws regulate the use of radio receivers and transmitters. Short
Range Devices (SRDs) for license free operation below 1 GHz are usually operated in the 315-MHz, 433MHz, 868-MHz or 915-MHz frequency bands. The CC1150 is specifically designed for such use with its
300 to 348 MHz, 400 to 464 MHz and 800 to 928 MHz operating ranges. The most important regulations
when using the CC1150 in the 315-MHz, 433-MHz, 868-MHz or 915-MHz frequency bands are EN 300
220 (Europe) and FCC CFR47 part 15 (USA). A summary of the most important aspects of these
regulations can be found in AN001 SRD Regulations for Licence Free Transceiver Operation (SWRA090).
NOTE
Compliance with regulations is dependent on complete system performance. It is the endproduct manufactor’s responsibility to ensure that the system complies with regulations.
5.19.2 Frequency Hopping and Multi-Channel Systems
The 315-MHz, 433-MHz, 868-MHz or 915-MHz bands are shared by many systems both in industrial,
office and home environments. It is therefore recommended to use frequency hopping spread spectrum
(FHSS) or a multi-channel protocol because the frequency diversity makes the system more robust with
respect to interference from other systems operating in the same frequency band. FHSS also combats
multipath fading.
CC1150 is highly suited for FHSS or multi-channel systems due to its agile frequency synthesizer and
effective communication interface. Using the packet handling support and data buffering is also beneficial
in such systems as these features will significantly offload the host controller.
Charge pump current, VCO current and VCO capacitance array calibration data is required for each
frequency when implementing frequency hopping for CC1150. There are 3 ways of obtaining the
calibration data from the chip:
1. Frequency hopping with calibration for each hop. The PLL calibration time is approximately 720 µs.
The blanking interval between each frequency hop is then approximately 810 µs.
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2. Fast frequency hopping without calibration for each hop can be done by calibrating each frequency at
startup and saving the resulting FSCAL3, FSCAL2 and FSCAL1 register values in MCU memory. The
VCO capacitance calibration FSCAL1 register value must be found for each RF frequency to be used.
The VCO current calibration value and the charge pump current calibration value available in FSCAL2
and FSCAL3 respectively are not dependent on the RF frequency, so the same value can therefore be
used for all RF frequencies for these two registers. Between each frequency hop, the calibration
process can then be replaced by writing the FSCAL3, FSCAL2 and FSCAL1 register values that
corresponds to the next RF frequency. The PLL turn on time is approximately 90 µs. The blanking
interval between each frequency hop is then approximately 90 µs.
3. Run calibration on a single frequency at startup. Next write 0 to FSCAL3[5:4] to disable the charge
pump calibration. After writing to FSCAL3[5:4], strobe STX with MCSM0.FS_AUTOCAL=1 for each
new frequency hop. That is, VCO current and VCO capacitance calibration is done, but not charge
pump current calibration. When charge pump current calibration is disabled the calibration time is
reduced from approximately 720 µs to approximately 150 µs. The blanking interval between each
frequency hop is then approximately 240 µs.
There is a trade off between blanking time and memory space needed for storing calibration data in nonvolatile memory. Solution (2) above gives the shortest blanking interval, but requires more memory space
to store calibration values. This solution also requires that the supply voltage and temperature do not vary
much in order to have a robust solution. Solution (3) gives approximately 570 µs smaller blanking interval
than solution (1).
The recommended settings for TEST0.VCO_SEL_CAL_EN change with frequency. This means that one
should always use SmartRF Studio [11] to get the correct settings for a specific frequency before doing a
calibration, regardless of which calibration method is being used. It must be noted that the content of the
CC1150 is not retained in SLEEP state, and thus it is necessary to write to the TEST0 register, along with
other registers, when returning from the SLEEP state and initiating calibrations.
5.19.3 Wideband Modulation Not Using Spread Spectrum
Digital modulation systems under FFC part 15.247 include FSK and GFSK modulation. A maximum peak
output power of 1W (+30 dBm) is allowed if the 6 dB bandwidth of the modulated signal exceeds 500 kHz.
In addition, the peak power spectral density conducted to the antenna shall not be greater than +8 dBm in
any 3 kHz band.
Operating at high data rates and frequency deviation the CC1150 is suited for systems targeting
compliance with digital modulation system as defined by FFC part 15.247. An external power amplifier is
needed to increase the output above +10 dBm. Please refer to DN006 [5] for further details concerning
wideband modulation and CC1150.
5.19.4 Data Burst Transmissions
The high maximum data rate of CC1150 opens up for burst transmissions. A low average data rate link
(for example, 10 kBaud), can be realized using a higher over-the-air data rate. Buffering the data and
transmitting in bursts at high data rate (for example, 500 kBaud) will reduce the time in active mode, and
hence also reduce the average current consumption significantly. Reducing the time in active mode will
reduce the likelihood of collisions with other systems in the same frequency range.
5.19.5 Continuous Transmissions
In data streaming applications the CC1150 opens up for continuous transmissions at 500 kBaud effective
data rate. As the modulation is done with a closed loop PLL, there is no limitation in the length of a
transmission (open loop modulation used in some transceivers often prevents this kind of continuous data
streaming and reduces the effective data rate).
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5.19.6 Low-Cost Systems
As the CC1150 provides 500-kBaud multi-channel performance without any external filters, a very low cost
system can be made. A HC-49 type SMD crystal is used in the CC1150EM reference design (see [1] and
[2]).
NOTE
The crystal package strongly influences the price. In a size constrained PCB design a
smaller, but more expensive, crystal may be used.
5.19.7 Battery-Operated Systems
In low power applications, the SLEEP state should be used when the CC1150 is not active.
5.19.8 Increasing Output Power
In some applications it may be necessary to extend the link range. Adding an external power amplifier is
the most effective way of doing this.
The power amplifier should be inserted between the antenna and the balun as shown in Figure 5-18.
Antenna
CC1150
BALUN,
Matching and
Filtering
PA
Filter
Figure 5-18. Block Diagram of CC1150 Usage with External Power Amplifier
5.20 Memory
The configuration of CC1150 is done by programming 8-bit registers. The configuration data based on
selected system parameters are most easily found by using the SmartRF Studio [11] software. Complete
descriptions of the registers are given in Section 5.20.1. After chip reset, all the registers have default
values as shown in the tables. The optimum register setting might differ from the default value. After a
reset, all registers that shall be different from the default value therefore needs to be programmed through
the SPI interface.
There are 9 Command Strobe Registers, listed in Table 5-11 Accessing these registers will initiate the
change of an internal state or mode. There are 29 normal 8-bit Configuration Registers, listed in Table 512. Many of these registers are for test purposes only, and need not be written for normal operation of
CC1150.
There are also 6 Status registers, which are listed in Table 5-13. These registers, which are read-only,
contain information about the status of CC1150.
The TX FIFO is accessed through one 8-bit register. Only write operations are allowed to the TX FIFO.
During the address transfer and while writing to a register or the TX FIFO, a status byte is returned. This
status byte is described in Table 5-2.
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Figure 5-19 summarizes the SPI address space. Registers that are only defined on the CC1101
transceiver are also listed. CC1101 and CC1150 are register compatible, but registers and fields only
implemented in the transceiver always contain 0 in CC1150.
The address to use is given by adding the base address to the left and the burst and read/write bits on the
top. Note that the burst bit has different meaning for base addresses above and below 0x2F.
Table 5-11. Command Strobes
ADDRESS
STROBE NAME
0x30
SRES
0x31
SFSTXON
0x32
SXOFF
0x33
SCAL
DESCRIPTION
Reset chip.
Enable and calibrate frequency synthesizer (if MCSM0.FS_AUTOCAL=1).
Turn off crystal oscillator.
Calibrate frequency synthesizer and turn it off (enables quick start). SCAL can be strobed in
IDLE state without setting manual calibration mode (MCSM0.FS_AUTOCAL=0)
0x35
STX
0x36
SIDLE
Enable TX. Perform calibration first if MCSM0.FS_AUTOCAL=1.
Exit TX and turn off frequency synthesizer.
0x39
SPWD
Enter power down mode when CSn goes high.
0x3B
SFTX
Flush the TX FIFO buffer.
0x3D
SNOP
No operation. May be used to pad strobe commands to two bytes for simpler software.
Table 5-12. Configuration Registers Overview
ADDRESS
ACRONYM
0x01
IOCFG1
GDO1 output pin configuration
REGISTER NAME
Table 5-14
SECTION
0x02
IOCFG0
GDO0 output pin configuration
Table 5-15
0x03
FIFOTHR
FIFO threshold
Table 5-16
0x04
SYNC1
Sync word, high byte
Table 5-17
0x05
SYNC0
Sync word, low byte
Table 5-18
0x06
PKTLEN
Packet length
Table 5-19
0x08
PKTCTRL0
Packet automation control
Table 5-20
0x09
ADDR
Device address
Table 5-21
0x0A
CHANNR
Channel number
Table 5-22
0x0D
FREQ2
Frequency control word, high byte
Table 5-23
0x0E
FREQ1
Frequency control word, middle byte
Table 5-24
0x0F
FREQ0
Frequency control word, low byte
Table 5-25
0x10
MDMCFG4
Modulator configuration
Table 5-26
0x11
MDMCFG3
Modulator configuration
Table 5-27
0x12
MDMCFG2
Modulator configuration
Table 5-28
0x13
MDMCFG1
Modulator configuration
Table 5-29
0x14
MDMCFG0
Modulator configuration
Table 5-30
0x15
DEVIATN
Modulator deviation setting
Table 5-31
0x17
MCSM1
Main Radio Control State Machine configuration
Table 5-32
0x18
MCSM0
Main Radio Control State Machine configuration
Table 5-33
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Table 5-12. Configuration Registers Overview (continued)
ADDRESS
ACRONYM
0x22
FREND0
Front end TX configuration
REGISTER NAME
Table 5-34
SECTION
0x23
FSCAL3
Frequency synthesizer calibration
Table 5-35
0x24
FSCAL2
Frequency synthesizer calibration
Table 5-36
0x25
FSCAL1
Frequency synthesizer calibration
Table 5-37
0x26
FSCAL0
Frequency synthesizer calibration
Table 5-38
0x29
FSTEST
Frequency synthesizer calibration control
Table 5-39
0x2A
PTEST
Production test
Table 5-40
0x2C
TEST2
Various test settings
Table 5-41
0x2D
TEST1
Various test settings
Table 5-42
0x2E
TEST0
Various test settings
Table 5-43
Table 5-13. Status Registers Overview
40
ADDRESS
ACRONYM
0x30 (0xF0)
PARTNUM
Part number for CC1150
REGISTER NAME
Table 5-44
0x31 (0xF1)
VERSION
Current version number
Table 5-45
0x35 (0xF5)
MARCSTATE
Control state machine state
Table 5-46
0x38 (0xF8)
PKTSTATUS
Current GDOx status and packet status
Table 5-47
0x39 (0xF9)
VCO_VC_DAC
Current setting from PLL calibration module
Table 5-48
0x3A (0xFA)
TXBYTES
Underflow and number of bytes in the TX FIFO
Table 5-49
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Read
Single byte
Burst
+0x80
+0xC0
IOCFG2
IOCFG1
IOCFG0
FIFOTHR
SYNC1
SYNC0
PKTLEN
PKTCTRL1
PKTCTRL0
ADDR
CHANNR
FSCTRL1
FSCTRL0
FREQ2
FREQ1
FREQ0
MDMCFG4
MDMCFG3
MDMCFG2
MDMCFG1
MDMCFG0
DEVIATN
MCSM2
MCSM1
MCSM0
FOCCFG
BSCFG
AGCCTRL2
AGCCTRL1
AGCCTRL0
WOREVT1
WOREVT0
WORCTRL
FREND1
FREND0
FSCAL3
FSCAL2
FSCAL1
FSCAL0
RCCTRL1
RCCTRL0
FSTEST
PTEST
AGCTEST
TEST2
TEST1
TEST0
Command Strobes, Status registers
(read only) and multi byte registers
0x00
0x01
0x02
0x03
0x04
0x05
0x06
0x07
0x08
0x09
0x0A
0x0B
0x0C
0x0D
0x0E
0x0F
0x10
0x11
0x12
0x13
0x14
0x15
0x16
0x17
0x18
0x19
0x1A
0x1B
0x1C
0x1D
0x1E
0x1F
0x20
0x21
0x22
0x23
0x24
0x25
0x26
0x27
0x28
0x29
0x2A
0x2B
0x2C
0x2D
0x2E
0x2F
0x30
SRES
SRES
PARTNUM
0x31
SFSTXON
SFSTXON
VERSION
0x32
SXOFF
SXOFF
FREQEST
0x33
SCAL
SCAL
LQI
0x34
SRX
SRX
RSSI
0x35
STX
STX
MARCSTATE
0x36
SIDLE
SIDLE
WORTIME1
0x37
SAFC
SAFC
WORTIME0
0x38
SWOR
SWOR
PKTSTATUS
0x39
SPWD
SPWD
VCO_VC_DAC
0x3A
SFRX
SFRX
TXBYTES
0x3B
SFTX
SFTX
RXBYTES
0x3C
SWORRST
SWORRST
0x3D
SNOP
SNOP
0x3E
PATABLE
PATABLE
PATABLE
PATABLE
0x3F
TX FIFO
TX FIFO
RX FIFO
RX FIFO
Greyed text: not implemented on CC1150 thus only valid for the transceiver version (CC1101)
R/W configuration registers, burst access possible
Write
Single byte
Burst
+0x00
+0x40
Figure 5-19. SPI Address Space
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5.20.1 Configuration Register Details
Table 5-14. 0x01: IOCFG1 – GDO1 Output Pin configuration
BIT
FIELD
TYPE
RESET
DESCRIPTION
7
GDO_DS
R/W
0x0
Set high (1) or low (0) output drive strength on the GDO pins.
6
GDO1_INV
R/W
0x0
Invert output, that is, select active low (1) / high (0).
5:0
GDO1_CFG[5:0]
R/W
0x2E
Default is tri-state (See Table 5-10).
Table 5-15. 0x02: IOCFG0 – GDO0 Output Pin Configuration
BIT
FIELD
TYPE
RESET
7
TEMP_SENSOR_ENABLE
R/W
0x0
Enable analog temperature sensor. Write 0 in all other register
bits when using temperature sensor.
DESCRIPTION
6
GDO0_INV
R/W
0x0
Invert output, that is, select active low (1) / high (0).
5:0
GDO0_CFG[5:0]
R/W
0x3F
Default is CLK_XOSC/192 (See Table 5-10).
It is recommended to disable the clock output during initialization
in order to optimize RF performance.
Table 5-16. 0x03: FIFOTHR – FIFO Threshold
BIT
FIELD
TYPE
RESET
7:4
Reserved
R/W
0x0
Write 0 for compatibility with possible future
extensions.
DESCRIPTION
3:0
FIFO_THR[3:0]
R/W
0x07
Set the threshold for the TX FIFO. The
threshold is exceeded when the number of
bytes in the FIFO is equal to or higher than the
threshold value.
The binary number is the setting and the result
(Bytes in TX FIFO) is the next state after
finishing packet transmission.
0000 = 61
0001 = 57
0010 = 53
0011 = 49
0100 = 45
0101 = 41
0110 = 37
0111 = 33
1000 = 29
1001 = 25
1010 = 21
1011 = 17
1100 = 13
1101 = 9
1110 = 5
1111 = 1
Table 5-17. 0x04: SYNC1 – Sync Word, High Byte
BIT
FIELD
TYPE
RESET
7:0
SYNC[15:8]
R/W
0xD3
DESCRIPTION
8 MSB of 16-bit sync word.
Table 5-18. 0x05: SYNC0 – Sync Word, Low Byte
42
BIT
FIELD
TYPE
RESET
7:0
SYNC[7:0]
R/W
0x91
Detailed Description
DESCRIPTION
8 LSB of 16-bit sync word.
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Table 5-19. 0x06: PKTLEN – Packet Length
BIT
FIELD
TYPE
RESET
DESCRIPTION
7:0
PACKET_LENGTH
R/W
0xFF
Indicates the packet length when fixed length
packets are enabled. If variable packet length
mode is used, this value indicates the
maximum packet length allowed.
Table 5-20. 0x08: PKTCTRL0 – Packet Automation Control
BIT
FIELD
TYPE
WHITE_DATA
R/W
7
6
RESET
R0
DESCRIPTION
Not Used.
0x1
Turn data whitening on / off
0: Whitening off
1: Whitening on
5:4
PKT_FORMAT[1:0]
R/W
0x0
Format of TX data:
The binary number is the setting and the result
is the packet format.
00 = Normal mode, use TX FIFO
01 = Serial Synchronous mode, data in on
GDO0
...
10 = Random TX mode; sends random
data using PN9 generator. Used for
test/debug.
11 = Asynchronous transparent mode.
Data in on GDO0
3
R/W
0x0
2
CRC_EN
R/W
0x1
1:0
LENGTH_CONFIG[1:0]
R/W
0x1
Not used.
1: CRC calculation enabled
0: CRC disabled
Configure the packet length:
The binary number is the setting and the result
is the packet length configuration.
00 = Fixed length packets, length
configured in PKTLEN register
01 = Variable length packets, packet length
configured by the first byte after sync word
10 = Infinite packet length packets
11 = Reserved
Table 5-21. 0x09: ADDR – Device Address
BIT
FIELD
TYPE
RESET
7:0
DEVICE_ADDRESS [7:0]
R/W
0x0
DESCRIPTION
Address used for packet filtration. Optional
broadcast addresses are 0 (0x00) and 255
(0xFF).
Table 5-22. 0x0A: CHANNR – Channel Number
BIT
FIELD
TYPE
RESET
7:0
CHAN[7:0]
R/W
0x0
DESCRIPTION
The 8-bit unsigned channel number, which is
multiplied by the channel spacing setting and
added to the base frequency.
Detailed Description
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Table 5-23. 0x0D: FREQ2 – Frequency Control Word, High Byte
BIT
FIELD
TYPE
RESET
DESCRIPTION
7:6
FREQ[23:22]
R
0x0
FREQ[23:22] is always 0 (the FREQ2 register
is less than 36 with 26 MHz or higher crystal
frequency).
5:0
FREQ[21:16]
R/W
0x1E
FREQ[23:0] is the base frequency for the
frequency synthesiser in increments of
FXOSC / 216.
fcarrier =
fxosc
216
´ FREQ [23 : 0]
(6)
Table 5-24. 0x0E: FREQ1 – Frequency Control Word, Middle Byte
BIT
FIELD
TYPE
RESET
7:0
FREQ[15:8]
R/W
0xC4
DESCRIPTION
Ref. FREQ2 register.
Table 5-25. 0x0F: FREQ0 – Frequency Control Word, Low Byte
BIT
FIELD
TYPE
RESET
7:0
FREQ[7:0]
R/W
0xEC
DESCRIPTION
Ref. FREQ2 register.
Table 5-26. 0x10: MDMCFG4 – Modulator Configuration
BIT
FIELD
TYPE
RESET
DESCRIPTION
7:4
Reserved
R0
0x08
Defined on the transceiver version (CC1101).
3:0
DRATE_E[3:0]
R/W
0x0C
The exponent of the user specified symbol
rate.
Table 5-27. 0x11: MDMCFG3 – Modulator Configuration
BIT
FIELD
TYPE
RESET
DESCRIPTION
7:0
DRATE_M[7:0]
R/W
0x22
The mantissa of the user specified symbol rate. The symbol rate is
configured using an unsigned, floating-point number with 9-bit
mantissa and 4-bit exponent. The 9th bit is a hidden ‘1’. The
resulting data rate is:
f
D fchannel = xosc
´ (256 + CHANSPC _ M) ´ 2CHANSPC _ E ´ CHAN
218
(7)
The default values give a data rate of 115.051 kBaud (closest
setting to 115.2 kBaud), assuming a 26.0 MHz crystal.
44
Detailed Description
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Table 5-28. 0x12: MDMCFG2 – Modulator Configuration
BIT
FIELD
TYPE
RESET
7
Reserved
R0
0x0
Defined on the transceiver version (CC1101).
DESCRIPTION
6:4
MOD_FORMAT[2:0]
R/W
0x0
The modulation format of the radio signal:
The binary number is the setting and the result is the
modulation format.
000 = 2-FSK
001 = GFSK
010 = N/A
011 = ASK/OOK
100 = N/A
101 = N/A
110 = N/A
111 = MSK
The OOK/ASK pulse shaping feature is only supported for
output powers up to –1 dBm.
MSK is only supported for data rates above 26 kBaud.
3
MANCHESTER_EN
0
0x0
Enables Manchester encoding/decoding.
0 = Disable
1 = Enable
2:0
SYNC_MODE[2:0]
2
0x2
Combined sync-word qualifier mode.
The values 0 (000) and 4 (100) disables preamble and sync
word transmission. The values 1 (001), 2 (010), 5 (101) and 6
(110) enables 16-bit sync word transmission. The values 3
(011) and 7 (111) enables repeated sync word transmission.
The binary number is the setting and the result is the Syncword qualifier mode (for compatibility with the CC1101
transceiver).
000 = No preamble/sync word
001 = 15/16 sync word bits detected
010 = 16/16 sync word bits detected
011 = 30/32 sync word bits detected
100 = No preamble/sync, carrier-sense above threshold
101 = 15/16 + carrier-sense above threshold
110 = 16/16 + carrier-sense above threshold
111 = 30/32 + carrier-sense above threshold
Table 5-29. 0x13: MDMCFG1 – Modulator Configuration
BIT
FIELD
TYPE
RESET
DESCRIPTION
7
FEC_EN
R/W
0x2
Enable Forward Error Correction (FEC) with interleaving
for packet payload
0 = Disable
1 = Enable (Only supported for fixed packet length
mode, that is, PKTCTRL0.LENGTH_CONFIG=0)
6:4
NUM_PREAMBLE[2:0]
R/W
0x2
Sets the minimum number of preamble bytes to be
transmitted.
The binary number is the setting and the result is the
minimum number of preamble bytes to be transmitted.
000 = 2
001 = 3
010 = 4
011 = 6
100 = 8
101 = 12
110 = 16
111 = 24
3:2
1:0
R0
CHANSPC_E[1:0]
R/W
Not Used.
0x2
2 bit exponent of channel spacing.
Detailed Description
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Table 5-30. 0x14: MDMCFG0 – Modulator Configuration
BIT
FIELD
TYPE
RESET
7:0
CHANSPC_M[7:0]
R/W
0xF8
DESCRIPTION
8-bit mantissa of channel spacing (initial 1 assumed).
The channel spacing is multiplied by the channel
number CHAN and added to the base frequency. It is
unsigned and has the format:
D fchannel =
fxosc
218
´ (256 + CHANSPC _ M) ´ 2CHANSPC _ E ´ CHAN
(8)
The default values give 199.951 kHz channel spacing
(the closest setting to 200 kHz), assuming 26.0 MHz
crystal frequency.
Table 5-31. 0x15: DEVIATN – Modulator Deviation Setting
BIT
FIELD
TYPE
DEVIATION_E[2:0]
R/W
7
RESET
R0
6:4
3
Not Used.
0x4
R0
2:0
DEVIATION_M[2:0]
R/W
DESCRIPTION
Deviation exponent.
Not Used.
0x7
When MSK modulation is enabled:
Specifies the fraction of symbol period (1/8-8/8) during
which a phase change occurs (‘0’: +90deg, ‘1’: –90deg).
Refer to the SmartRF Studio [11] software for correct
DEVIATN setting when using MSK.
When 2-FSK/GFSK modulation is enabled:
Deviation mantissa, interpreted as a 4-bit value with MSB
implicit 1. The resulting frequency deviation is given by
Equation 9:
fdev =
fxosc
217
´ (8 + DEVIATION _ M) ´ 2DEVIATION _ E
(9)
The default values give ±47.607 kHz deviation, assuming
26.0 MHz crystal frequency.
When ASK/OOK modulation is enabled:
This setting has no effect.
Table 5-32. 0x17: MCSM1 – Main Radio Control State Machine Configuration
BIT
FIELD
7:6
TYPE
RESET
R0
DESCRIPTION
Not Used.
5:2
Reserved
R0
0x0C
1:0
TXOFF_MODE[1:0]
R/W
0x0
Defined on the transceiver version (CC1101).
Select what should happen when a packet has been
sent (TX):
The binary number is the setting and the result is the
next state after finishing packet transmission.
00
01
10
11
46
Detailed Description
= IDLE
= FSTXON
= Stay in TX (start sending preamble)
= Do not use, not implemented on CC1150
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Table 5-33. 0x18: MCSM0 – Main Radio Control State Machine Configuration
BIT
FIELD
7:6
5:4
TYPE
RESET
R0
FS_AUTOCAL[1:0]
DESCRIPTION
Not Used.
R/W
0x0
Automatically calibrate when going to TX, or back to
IDLE:
The binary number is the setting and the result is when
to perform automatic calibration.
00
01
10
11
3:2
PO_TIMEOUT
R/W
0x1
= Never (manually calibrate using SCAL strobe)
= When going from IDLE to TX (or FSTXON)
= When going from TX back to IDLE
= Every 4th time when going from TX to IDLE
Programs the number of times the six-bit ripple counter
must expire after XOSC has stabilized before
CHP_RDY_N goes low.
The XOSC is off during power-down and if the regulated
digital supply voltage has sufficient time to stabilize while
waiting for the crystal to be stable, PO_TIMEOUT can be
set to 0. For robust operation it is recommended to use
PO_TIMEOUT=2.
The binary number is the setting, the result is the expire
count, and the definition is the timeout after XOSC start.
00 = 1 : Approx. 2.3 μs – 2.7 μs
01 = 16 : Approx. 37 μs – 43 μs
10 = 64 : Approx. 146 μs – 171 μs
11 = 256 : Approx. 585 μs – 683 μs
Exact timeout depends on crystal frequency.
In order to reduce start up time from the SLEEP state,
this field is preserved in powerdown (SLEEP state).
1:0
Reserved
R0
Defined on the transceiver version (CC1101)
Table 5-34. 0x22: FREND0 – Front End TX Configuration
BIT
FIELD
TYPE
LODIV_BUF_
CURRENT_TX[1:0]
R/W
PA_POWER[2:0]
R/W
7:6
5:4
R0
3
2:0
RESET
DESCRIPTION
Not Used.
0x1
R0
Adjusts current TX LO buffer (input to PA).
The value to use in register field is given by
the SmartRF Studio [11] software.
Not Used.
0x0
Selects PA power setting. This value is an
index to the PATABLE, which can be
programmed with up to 8 different PA
settings. In ASK mode, this selects the
PATABLE index to use when transmitting a
‘1’. PATABLE index zero is used in ASK when
transmitting a ‘0’. The PATABLE settings from
index ‘0’ to the PA_POWER value are used
for ASK TX shaping, and for power rampup/ramp-down at the start/end of transmission
in all TX modulation formats.
Detailed Description
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Table 5-35. 0x23: FSCAL3 – Frequency Synthesizer Calibration
BIT
FIELD
TYPE
RESET
7:6
FSCAL3[7:6]
R/W
0x02
Frequency synthesizer calibration
configuration. The value to write in this field
before calibration is given by the SmartRF
Studio software.
DESCRIPTION
5:4
CHP_CURR_CAL_EN[1:0]
R/W
0x02
Disable charge pump calibration stage when
0.
3:0
FSCAL3[3:0]
R/W
0x09
Frequency synthesizer calibration result
register. Digital bit vector defining the charge
pump output current, on an exponential scale:
I_OUT = I0·2FSCAL3[3:0]/4.
Fast frequency hopping without calibration for
each hop can be done by calibrating up front
for each frequency and saving the resulting
FSCAL3, FSCAL2 and FSCAL1 register
values. Between each frequency hop,
calibration can be replaced by writing the
FSCAL3, FSCAL2 and FSCAL1 register
values corresponding to the next RF
frequency.
Table 5-36. 0x24: FSCAL2 – Frequency Synthesizer Calibration
BIT
FIELD
TYPE
5
VCO_CORE_H_EN
R/W
0x0
5:0
FSCAL2[5:0]
R/W
0x0A
7:6
RESET
R0
DESCRIPTION
Not Used.
Choose high (1)/ low (0) VCO.
Frequency synthesizer calibration result register. VCO
current calibration result and override value.
Fast frequency hopping without calibration for each
hop can be done by calibrating up front for each
frequency and saving the resulting FSCAL3, FSCAL2
and FSCAL1 register values. Between each frequency
hop, calibration can be replaced by writing the
FSCAL3, FSCAL2 and FSCAL1 register values
corresponding to the next RF frequency.
Table 5-37. 0x25: FSCAL1 – Frequency Synthesizer Calibration
BIT
FIELD
7:6
5:0
TYPE
RESET
R0
FSCAL1[5:0]
DESCRIPTION
Not Used.
R/W
0x20
Frequency synthesizer calibration result register. Capacitor
array setting for VCO coarse tuning.
Fast frequency hopping without calibration for each hop
can be done by calibrating up front for each frequency and
saving the resulting FSCAL3, FSCAL2 and FSCAL1
register values. Between each frequency hop, calibration
can be replaced by writing the FSCAL3, FSCAL2 and
FSCAL1 register values corresponding to the next RF
frequency.
Table 5-38. 0x26: FSCAL0 – Frequency Synthesizer Calibration
BIT
FIELD
TYPE
7
Reserved
R0
6:0
FSCAL0[6:0]
R/W
RESET
DESCRIPTION
Not Used.
0x0D
Frequency synthesizer calibration control. The
value to use in register field is given by the
SmartRF Studio [11] software.
Table 5-39. 0x29: FSTEST – Frequency Synthesizer Calibration Control
48
BIT
FIELD
TYPE
RESET
7:0
FSTEST[7:0]
R/W
0x57
Detailed Description
DESCRIPTION
For test only. Do not write to this register.
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Table 5-40. 0x2A: PTEST – Production Test
BIT
FIELD
TYPE
RESET
DESCRIPTION
7:0
PTEST[7:0]
R/W
0x7F
Writing 0xBF to this register makes the onchip temperature sensor available in the IDLE
state. The default 0x7F value should then be
written back before leaving the IDLE state.
Other use of this register is for test only.
Table 5-41. 0x2C: TEST2 – Various Test Settings
BIT
FIELD
TYPE
7:0
TEST2[7:0]
R/W
RESET
DESCRIPTION
The value to use in this register is given by
the SmartRF Studio [11] software.
Table 5-42. 0x2D: TEST1 – Various Test Settings
BIT
FIELD
TYPE
RESET
7:0
TEST1[7:0]
R/W
0x21
DESCRIPTION
The value to use in this register is given by
the SmartRF Studio [11] software.
Table 5-43. 0x2E: TEST0 – Various Test Settings
BIT
FIELD
TYPE
RESET
7:2
TEST0[7:2]
R/W
0x02
The value to use in this register is given by
the SmartRF Studio [11] software.
DESCRIPTION
1
VCO_SEL_CAL_EN
R/W
0x1
Enable VCO selection calibration stage when
1. The value to use in this register is given by
the SmartRF Studio [11] software.
0
TEST0[0]
R/W
0x1
The value to use in this register is given by
the SmartRF Studio [11] software.
5.20.2 Status Register Details
Table 5-44. 0x30 (0xF0): PARTNUM – Chip ID
BIT
FIELD
TYPE
RESET
7:0
PARTNUM[7:0]
R
0x02
DESCRIPTION
Chip part number.
Table 5-45. 0x31 (0xF1): VERSION – Chip ID
BIT
FIELD
TYPE
RESET
7:0
VERSION[7:0]
R
0x04
DESCRIPTION
Chip version number.
Subject to change without notice
Detailed Description
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Table 5-46. 0x35 (0xF5): MARCSTATE – Main Radio Control State Machine State
BIT
FIELD
TYPE
7:5
Reserved
R0
4:0
MARC_STATE[4:0]
R
RESET
DESCRIPTION
Main Radio Control FSM State (1)
The bit enumerations show the value, the state name, and
the state (2).
0x00 = SLEEP : SLEEP
0x01 = IDLE : IDLE
0x02 = XOFF : XOFF
0x03 = VCOON_MC : MANCAL
0x04 = REGON_MC : MANCAL
0x05 = MANCAL : MANCAL
0x06 = VCOON : FS_WAKEUP
0x07 = REGON : FS_WAKEUP
0x08 = STARTCAL : CALIBRATE
0x09 = BWBOOST : SETTLING
0x0A = FS_LOCK : SETTLING
0x0B = N/A : N/A
0x0C = ENDCAL : CALIBRATE
0x0D = N/A : N/A
0x0E = N/A : N/A
0x0F = N/A : N/A
0x10 = N/A : N/A
0x11 = N/A : N/A
0x12 = FSTXON : FSTXON
0x13 = TX : TX
0x14 = TX_END : TX
0x15 = N/A : N/A
0x16 = TX_UNDERFLOW : TX_UNDERFLOW
(1)
(2)
It is not possible to read back the SLEEP or XOFF state numbers because setting CSn low will make the chip enter the IDLE mode from
the SLEEP or XOFF states.
State (see Figure 5-11).
Table 5-47. 0x38 (0xF8): PKTSTATUS – Current GDOx Status
BIT
FIELD
TYPE
7:2
Reserved
R0
Defined on the transceiver version (CC1101).
R0
Not Used.
R
Current GDO0 value. Note: the reading gives the
non-inverted value irrespective what
IOCFG0.GDO0_INV is programmed to.
It is not recommended to check for PLL lock by
reading PKTSTATUS[0] with GDO0_CFG = 0x0A.
1
0
GDO0
RESET
DESCRIPTION
Table 5-48. 0x39 (0xF9): VCO_VC_DAC – Current Setting from PLL Calibration Module
BIT
FIELD
TYPE
7:0
VCO_VC_DAC[7:0]
R
RESET
DESCRIPTION
Status registers for test only.
Table 5-49. 0x3A (0xFA): TXBYTES – Underflow and Number of Bytes
50
BIT
FIELD
7
TXFIFO_UNDERFLOW
TYPE
RESET
R
6:0
NUM_TXBYTES
R
Detailed Description
DESCRIPTION
Number of bytes in TX FIFO.
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6 Applications, Implementation, and Layout
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
6.1
6.1.1
Application Information
Typical Application
A simplified block diagram of CC1150 is shown in Figure 5-1.
Only a few external components are required for using the CC1150. The recommended application circuits
are shown in Figure 6-1 and Figure 6-2. The external components are described in Table 6-1, and typical
values are given in Table 6-2.
1.8 V-3.6 V power supply
R141
1 SCLK
SO
(GDO1)
2 SO
(GDO1)
Antenna
(50 Ohm)
AVDD 13
RBIAS 14
DGUARD 15
SCLK
AVDD 12
CC1150
C111
L111
C105
RF_N 11
DIE ATTACH PAD:
3 DVDD
CSn 9
8 GDO0
7 XOSC_Q2
C41
6 AVDD
4 DCOUPL
RF_P 10
5 XOSC_Q1
Digital Inteface
SI 16
SI
C101
L101
L102
L103
C102
C103
C104
GDO0
(optional)
CSn
XTAL
C51
C71
Figure 6-1. Typical Application and Evaluation Circuit 315/433 MHz
(Excluding Supply Decoupling Capacitors)
Applications, Implementation, and Layout
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1.8 V-3.6 V power supply
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R141
1 SCLK
SO
(GDO1)
2 SO
(GDO1)
AVDD 13
RBIAS 14
DGUARD 15
SCLK
AVDD 12
C105
RF_N 11
C101
3 DVDD
L103
L104
CSn 9
8 GDO0
7 XOSC_Q2
RF_P 10
6 AVDD
C41
L112
L111
DIE ATTACH PAD:
4 DCOUPL
Antenna
(50 Ohm)
C111
CC1150
5 XOSC_Q1
Digital Inteface
SI 16
SI
L101
L102
C103
C102
C106 and L105 may
be added to build an
optional filter to reduce
emission at 699 MHz
C104
GDO0
(optional)
CSn
L105
C106
XTAL
C51
C71
Figure 6-2. Typical Application and Evaluation Circuit 868/915 MHz
(Excluding Supply Decoupling Capacitors)
Table 6-1. Overview of External Components (Excluding Supply Decoupling Capacitors)
COMPONENT
C41
C51/C71
C101/C111
52
DESCRIPTION
Decoupling capacitor for on-chip voltage regulator to digital part
Crystal loading capacitors
RF balun/matching capacitors
C102
RF LC filter/matching filter capacitor (315 and 433 MHz). RF balun/matching capacitor (868/915 MHz).
C103
RF LC filter/matching capacitors
C104
RF balun DC blocking capacitor
C105
RF LC filter DC blocking capacitor and part of optional RF LC filter (868/915 MHz)
C106
Part of optional RF LC filter and DC Block (868/915 MHz)
L101/L111
RF balun/matching inductors (inexpensive multi-layer type)
L102
RF LC filter/matching filter inductor (315 and 433 MHz). RF balun/matching inductor (868/915 MHz)
(inexpensive multi-layer type)
L103
RF LC filter/matching inductor (inexpensive multi-layer type)
L104
RF LC filter/matching inductor (inexpensive multi-layer type)
L105
Part of optional RF LC filter (868/915 MHz)(inexpensive multi-layer type)
R141
Resistor for internal bias current reference
XTAL
26 to 27 MHz crystal
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Table 6-2. Bill of Materials for the Application Circuit (1)
COMPONENT
VALUE @ 31 5MHz
VALUE @ 433 MHz
C41
100 nF ± 10%, 0402 X5R
C51
27 pF ± 5%, 0402 NP0
C71
27 pF ± 5%, 0402 NP0
C101
6.8 pF ± 0.5 pF, 0402 NP0
3.9 pF ± 0.25 pF, 0402 NP0
1.0 pF ± 0.25 pF, 0402 NP0
C102
12 pF ± 5%, 0402 NP0
8.2 pF ± 0.5 pF, 0402 NP0
1.5 pF ± 0.25 pF, 0402 NP0
C103
6.8 pF ± 0.5 pF, 0402 NP0
5.6 pF ± 0.5pF, 0402 NP0
3.3 pF ± 0.25 pF, 0402 NP0
C104
220 pF ± 5%, 0402 NP0
220 pF ± 5%, 0402 NP0
100 pF ± 5%, 0402 NP0
C105
220 pF ± 5%, 0402 NP0
220 pF ± 5%, 0402 NP0
100 pF ± 5%, 0402 NP0
(12 pF ± 5%, 0402 NP0 if optionally
699 MHz filter is desired)
(47 pF ± 5%, 0402 NP0 if optionally
699 MHz filter is desired)
C106
C111
6.8 pF ± 0.5 pF, 0402 NP0
3.9 pF ± 0.25 pF, 0402 NP0
1.5 pF ± 0.25pF, 0402 NP0
L101
33 nH ± 5%, 0402 monolithic
27 nH ± 5%, 0402 monolithic
12 nH ± 5%, 0402 monolithic
L102
18 nH ± 5%, 0402 monolithic
22 nH ± 5%, 0402 monolithic
18 nH ± 5%, 0402 monolithic
L103
33 nH ± 5%, 0402 monolithic
27 nH ± 5%, 0402 monolithic
L105
L111
12 nH ± 5%, 0402 monolithic
(12 nH ± 5%, 0402 monolithic if
optionally 699 MHz filter is desired)
L104
3.3 nH ± 5%, 0402 monolithic
33 nH ± 5%, 0402 monolithic
27 nH ± 5%, 0402 monolithic
L112
(1)
VALUE @ 868/915 MHz
12 nH ± 5%, 0402 monolithic
18 nH ± 5%, 0402 monolithic
R141
56 kΩ ±1%, 0402
XTAL
26.0 MHz surface mount crystal
Murata LQG15HS and GRM1555C series inductors and capacitors, resistor from the Koa RK73 series, and AT-41CD2 crystal from NDK
6.2
6.2.1
Design Requirements
Bias Resistor
The bias resistor R141 is used to set an accurate bias current.
6.2.2
Balun and RF Matching
The components between the RF_N/RF_P pins and the point where the two signals are joined together
[(C111, C101, L101 and L111 for the 315/433 MHz design) and (L101, L111, C101, L102, C111, C102
and L112 for the 868/915 MHz reference design)] form a balun that converts the differential RF signal on
CC1150 to a single-ended RF signal. C104 is needed for dc blocking. Together with an appropriate LC
filter network, the balun components also transform the impedance to match a 50-Ω antenna (or cable).
C105 provides dc blocking and is only needed if there is a dc path in the antenna. For the 868/915 MHz
reference design, this component may also be used for additional filtering, see Section 6.2.5.
Suggested values for 315 MHz, 433 MHz, and 868/915 MHz are listed in Table 6-2.
The balun and LC filter component values and their placement are important to achieve optimal
performance. It is highly recommended to follow the CC1150EM reference design (see [1] and [2]). Gerber
files and schematics for the reference designs are available for download from CC1150EM433 and
CC1150EM868.
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Crystal
A crystal in the frequency range of 26 to 27 MHz must be connected between the XOSC_Q1 and
XOSC_Q2 pins. The oscillator is designed for parallel mode operation of the crystal. In addition, loading
capacitors (C51 and C71) for the crystal are required. The loading capacitor values depend on the total
load capacitance, CL , specified for the crystal. The total load capacitance seen between the crystal
terminals should equal CL for the crystal to oscillate at the specified frequency.
1
CL =
+ Cparasitic
1
1
+
C51
C71
(10)
The parasitic capacitance is constituted by pin input capacitance and PCB stray capacitance. Total
parasitic capacitance is typically 2.5 pF.
The crystal oscillator circuit is shown in Figure 6-3. Typical component values for different values of CL are
given in Table 6-3.
XOSC_Q1
XOSC_Q2
XTAL
C51
C71
Figure 6-3. Crystal Oscillator Circuit
The crystal oscillator is amplitude regulated. This means that a high current is used to start up the
oscillations. When the amplitude builds up, the current is reduced to what is necessary to maintain
approximately 0.4 Vpp signal swing. This ensures a fast start up, and keeps the drive level to a minimum.
The ESR of the crystal should be within the specification in order to ensure a reliable start up (see
Section 4.7).
The initial tolerance, temperature drift, aging and load pulling should be carefully specified in order to meet
the required frequency accuracy in a certain application.
Table 6-3. Crystal Oscillator Component Values
54
COMPONENT
CL= 10 pF
CL= 13 pF
CL= 16 pF
C51
15 pF
22 pF
27 pF
C71
15 pF
22 pF
27 pF
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Reference Signal
The chip can alternatively be operated with a reference signal from 26 to 27 MHz instead of a crystal. This
input clock can either be a full-swing digital signal (0 V to VDD) or a sine wave of maximum 1-V peak-topeak amplitude. The reference signal must be connected to the XOSC_Q1 input. The sine wave must be
connected to XOSC_Q1 using a serial capacitor. The XOSC_Q2 line must be left unconnected. C51 and
C71 can be omitted when using a reference signal.
6.2.5
Additional Filtering
In the 868/915 MHz reference design, C106 and L105 together with C105 build an optional filter to reduce
emission at 699 MHz. This filter may be necessary for applications seeking compliance with ETSI EN 300220, for more information, see DN017 [6]. If this filtering is not necessary, C105 will work as a DC block
(only necessary if there is a DC path in the antenna). C106 and L105 should in that case be left
unmounted.
Additional external components (for example, an RF SAW filter) may be used in order to improve the
performance in specific applications. The use of wire-wound inductors in the application circuit will also
improve the RF performance and give higher output power. For more information, see DN017 [6].
6.2.6
Power Supply Decoupling
The power supply must be properly decoupled close to the supply pins.
NOTE
Decoupling capacitors are not shown in the application circuit. The placement and the size of
the decoupling capacitors are very important to achieve the optimum performance.
The CC1150EM reference design should be followed closely (see [1] and [2]).
6.3
PCB Layout Recommendations
The top layer should be used for signal routing, and the open areas should be filled with metallization
connected to ground using several vias.
The area under the chip is used for grounding and shall be connected to the bottom ground plane with
several vias for good thermal performance and sufficiently low inductance to ground.
In the CC1150EM reference designs (see [1] and [2]), 5 vias are placed inside the exposed die attached
pad. These vias should be “tented” (covered with solder mask) on the component side of the PCB to avoid
migration of solder through the vias during the solder-reflow process.
The solder paste coverage should not be 100%. If it is, out gassing may occur during the reflow process,
which may cause defects (splattering, solder balling). Using “tented” vias reduces the solder paste
coverage below 100%. See Figure 6-4 for top solder resist and top paste masks.
All the decoupling capacitors should be placed as close as possible to the supply pin it is supposed to
decouple. Each decoupling capacitor should be connected to the power line (or power plane) by separate
vias. The best routing is from the power line (or power plane) to the decoupling capacitor and then to the
CC1150 supply pin. Supply power filtering is very important.
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Each decoupling capacitor ground pad should be connected to the ground plane by separate vias. Direct
connections between neighboring power pins will increase noise coupling and should be avoided unless
absolutely necessary. Routing in the ground plane underneath and between the chip, the balun/RF
matching circuit and the decoupling capacitor’s ground vias should also be avoided. This improves the
grounding and ensures the shortest possible return path for stray currents.
The external components should ideally be as small as possible (0402 is recommended) and surface
mount devices are highly recommended. Please note that components smaller than those specified may
have differing characteristics.
Precaution should be used when placing the microcontroller in order to avoid noise interfering with the RF
circuitry.
It is strongly advised that the CC1150EM reference design (see [1] and [2]) layout is followed very closely
in order to get the best performance. Gerber files and schematics for the reference designs are available
for download from the TI website.
Circles are Vias
Figure 6-4. Left: Top Solder Resist Mask (Negative) and Right: Top Paste Mask
56
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Package Description (QLP 16)
Figure 6-5. Recommended PCB Layout for Package (QLP 16)
Figure 6-5 is an illustration only and not to scale. There are five 10-mil diameter via holes distributed
symmetrically in the ground pad under the package. See also the CC1150EM reference design ( [1] and
[2]).
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7 Device and Documentation Support
7.1
7.1.1
Device Support
Device Nomenclature
To designate the stages in the product development cycle, TI assigns prefixes to the part numbers. Each
device has one of three prefixes: X, P, or null (no prefix) (for example, CC1150 is in production; therefore,
no prefix is assigned).
Device development evolutionary flow:
X
Experimental device that is not necessarily representative of the final device's electrical
specifications and may not use production assembly flow.
P
Prototype device that is not necessarily the final silicon die and may not necessarily meet
final electrical specifications.
null
Production version of the silicon die that is fully qualified.
Production devices have been characterized fully, and the quality and reliability of the device have been
demonstrated fully. TI's standard warranty applies.
Predictions show that prototype devices (X or P) have a greater failure rate than the standard production
devices. Texas Instruments recommends that these devices not be used in any production system
because their expected end-use failure rate still is undefined. Only qualified production devices are to be
used.
TI device nomenclature also includes a suffix with the device family name. This suffix indicates the
package type (for example, RGV).
For orderable part numbers of CC1150 devices in the RGV
package types, see the Package Option Addendum of this document, the TI website (www.ti.com), or
contact your TI sales representative.
7.2
Documentation Support
The following documents describe the CC1150 device. Copies of these documents are available on the
Internet at www.ti.com.
1. [1] CC1150EM 315 – 433 MHz Reference Design (SWRR041)
2. [2] CC1150EM 868 – 915 MHz Reference Design (SWRR042)
3. [3] DN012 Programming Output Power on CC1100 and CC1150 (SWRA150)
4. [5] DN006 CC11xx Settings for FCC 15.247 Solutions (SWRA123)
5. [6] DN017 CC11xx 868/915 MHz Matching (SWRA168)
6. [7] AN058 Antenna Selection Guide (SWRA161)
7. [8] CC1150 Errata Notes (SWRZ018)
8. [9] DN501 PATABLE Access (SWRA110)
9. [10] AN001 SRD Regulations for Licence Free Transceiver Operation (SWRA090)
10. [11] (SmartRF Studio)
11. [12] CC1100/CC1150DK and CC2500/CC2550DK Development Kit Examples and Libraries User
Manual (SWRU109)
7.2.1
Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the
respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views;
see TI's Terms of Use.
58
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TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster
collaboration among engineers. At e2e.ti.com, you can ask questions, share knowledge,
explore ideas and help solve problems with fellow engineers.
TI Embedded Processors Wiki Texas Instruments Embedded Processors Wiki. Established to help
developers get started with Embedded Processors from Texas Instruments and to foster
innovation and growth of general knowledge about the hardware and software surrounding
these devices.
7.3
Trademarks
SmartRF, E2E are trademarks of Texas Instruments.
7.4
Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
7.5
Export Control Notice
Recipient agrees to not knowingly export or re-export, directly or indirectly, any product or technical data
(as defined by the U.S., EU, and other Export Administration Regulations) including software, or any
controlled product restricted by other applicable national regulations, received from disclosing party under
nondisclosure obligations (if any), or any direct product of such technology, to any destination to which
such export or re-export is restricted or prohibited by U.S. or other applicable laws, without obtaining prior
authorization from U.S. Department of Commerce and other competent Government authorities to the
extent required by those laws.
7.6
Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
8 Mechanical Packaging and Orderable Information
8.1
Packaging Information
The following pages include mechanical packaging and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and
revision of this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
Copyright © 2006–2015, Texas Instruments Incorporated
Mechanical Packaging and Orderable Information
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PACKAGE OPTION ADDENDUM
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15-Apr-2017
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Op Temp (°C)
Device Marking
(4/5)
CC1150-RTR1
OBSOLETE
VQFN
RST
16
TBD
Call TI
Call TI
-40 to 85
CC1150
CC1150-RTY1
OBSOLETE
VQFN
RST
16
TBD
Call TI
Call TI
-40 to 85
CC1150
CC1150RGVR
ACTIVE
VQFN
RGV
16
2500
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
-40 to 85
CC1150
CC1150RGVT
ACTIVE
VQFN
RGV
16
250
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
-40 to 85
CC1150
CC1150RST
OBSOLETE
VQFN
RST
16
TBD
Call TI
Call TI
-40 to 85
CC1150
CC1150RSTR
OBSOLETE
VQFN
RST
16
TBD
Call TI
Call TI
-40 to 85
CC1150
HPA00452RSTR
OBSOLETE
VQFN
RST
16
TBD
Call TI
Call TI
-40 to 85
CC1150
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
15-Apr-2017
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
21-Nov-2016
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
CC1150RGVR
VQFN
RGV
16
2500
330.0
12.4
4.3
4.3
1.5
8.0
12.0
Q2
CC1150RGVT
VQFN
RGV
16
250
180.0
12.4
4.3
4.3
1.5
8.0
12.0
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
21-Nov-2016
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
CC1150RGVR
VQFN
RGV
16
2500
336.6
336.6
28.6
CC1150RGVT
VQFN
RGV
16
250
210.0
185.0
35.0
Pack Materials-Page 2
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