TI CC115L

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TI德州仪器无线链接产品数据手册
CC115L
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信驰达简介
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CC115L
超值系列 (Value Line) 发送器
特性
1
•
•
•
主要特性
– 可编程输出功率高达 +12 dBm（对于所有支持
的频率）
– 可编程数据速率：范围是 0.6 至 600 kbps
– 频段：300 - 348 MHz、387 - 464 MHz 和 779
- 928 MHz
– 支持 2-FSK、4-FSK、GFSK、MSK 和 OOK
数字特性
– 可灵活地支持面向分组的系统
– 对同步字插入、灵活和分组长度及自动 CRC 计
算提供了片上支持
低功耗特性
– 200nA 睡眠模式电流消耗
– 快速启动时间：240 μs（从睡眠模式到发送
[TX] 模式）
– 64 字节 TX FIFO
应用
•
•
•
•
•
•
•
工作于 315 / 433 / 868 / 915 MHz ISM / SRD 频段
的超低功耗无线应用
无线报警和安全系统
工业监测和控制
遥控
玩具
家庭和楼宇自动化
有源 RFID
常规
•
极少的外部组件；全集成化频率合成器
•
绿色环保型封装：符合 RoHS 标准，并且不含锑或
溴
•
小尺寸（采用 QLP 4x4 mm 封装，20 引脚）
•
适合那些旨在符合 EN 300 220（欧洲）和 FCC
CFR Part 15（美国）标准的系统
•
支持异步及同步串行发送模式，以返回兼容现有的
射频通信协议
说明
CC115L 是一款成本优化的 sub-1 GHz RF 发送器。该电路基于受欢迎的 CC1101 RF 收发器，而且 RF 性能特征
相同。 CC115L 超值系列发送器与 CC113L 超值系列接收器一起实现了低成本的 RF 链路。
RF 发送器与一个可配置的基带调制器实现了集成。该调制解调器支持各种调制格式，并且具有 0.6 至 600kbps 的
可配置数据速率。
CC115L 提供了针对分组处理、数据缓冲和突发传输的丰富硬件支持。
CC115L 的主要工作参数及 64 字节发送 FIFO 可通过一个 SPI 接口进行控制。在一般系统中，CC115L 将与微控
制器和少量的附加无源组件配合使用。
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CC115L
Abbreviations
Abbreviations used in this data sheet are described below.
2-FSK
Binary Frequency Shift Keying
MCU
Microcontroller Unit
4-FSK
Quaternary Frequency Shift Keying
MSB
Most Significant Bit
ADC
Analog to Digital Converter
N/A
Not Applicable
AMR
Automatic Meter Reading
NRZ
Non Return to Zero (Coding)
BOM
Bill of Material
OOK
On-Off Keying
BT
Bandwidth-Time product
PA
Power Amplifier
CFR
Code of Federal Regulations
PCB
Printed Circuit Board
CRC
Cyclic Redundancy Check
PD
Power Down
CW
Continuous Wave (Unmodulated Carrier)
PER
Packet Error Rate
DC
Direct Current
PLL
Phase Locked Loop
ESR
Equivalent Series Resistance
POR
Power-On Reset
FCC
Federal Communications Commission
QLP
Quad Leadless Package
FIFO
First-In-First-Out
QPSK
Quadrature Phase Shift Keying
FS
Frequency Synthesizer
RC
Resistor-Capacitor
GFSK
Gaussian shaped Frequency Shift Keying
RF
Radio Frequency
IF
Intermediate Frequency
SPI
Serial Peripheral Interface
I/Q
In-Phase/Quadrature
SRD
Short Range Devices
ISM
Industrial, Scientific, Medical
TX
Transmit, Transmit Mode
LC
Inductor-Capacitor
VCO
Voltage Controlled Oscillator
LO
Local Oscillator
XOSC
Crystal Oscillator
LSB
Least Significant Bit
XTAL
Crystal
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CC115L
Table Of Contents
APPLICATIONS .................................................................................................................................................. 1
KEY FEATURES ................................................................................................................................................. 1
RF PERFORMANCE .......................................................................................................................................... 1
DIGITAL FEATURES......................................................................................................................................... 1
LOW-POWER FEATURES ................................................................................................................................ 1
GENERAL ............................................................................................................................................................ 1
PRODUCT DESCRIPTION ................................................................................................................................ 1
ABBREVIATIONS ............................................................................................................................................... 2
TABLE OF CONTENTS ..................................................................................................................................... 3
1
ABSOLUTE MAXIMUM RATINGS ..................................................................................................... 5
2
OPERATING CONDITIONS ................................................................................................................. 5
3
GENERAL CHARACTERISTICS ......................................................................................................... 5
4
ELECTRICAL SPECIFICATIONS ....................................................................................................... 6
4.1
CURRENT CONSUMPTION ............................................................................................................................ 6
4.2
RF TRANSMIT SECTION ............................................................................................................................... 7
4.3
CRYSTAL OSCILLATOR ................................................................................................................................ 9
4.4
FREQUENCY SYNTHESIZER CHARACTERISTICS ............................................................................................ 9
4.5
DC CHARACTERISTICS .............................................................................................................................. 10
4.6
POWER-ON RESET ..................................................................................................................................... 10
5
PIN CONFIGURATION ........................................................................................................................ 10
6
CIRCUIT DESCRIPTION .................................................................................................................... 12
7
APPLICATION CIRCUIT .................................................................................................................... 12
7.1
BIAS RESISTOR .......................................................................................................................................... 12
7.2
BALUN AND RF MATCHING ....................................................................................................................... 13
7.3
CRYSTAL ................................................................................................................................................... 14
7.4
REFERENCE SIGNAL .................................................................................................................................. 15
7.5
ADDITIONAL FILTERING ............................................................................................................................ 15
7.6
POWER SUPPLY DECOUPLING .................................................................................................................... 15
7.7
PCB LAYOUT RECOMMENDATIONS ........................................................................................................... 15
8
CONFIGURATION OVERVIEW ........................................................................................................ 17
9
CONFIGURATION SOFTWARE ........................................................................................................ 18
10
4-WIRE SERIAL CONFIGURATION AND DATA INTERFACE .................................................. 18
10.1 CHIP STATUS BYTE ................................................................................................................................... 19
10.2 REGISTER ACCESS ..................................................................................................................................... 20
10.3 SPI READ .................................................................................................................................................. 20
10.4 COMMAND STROBES ................................................................................................................................. 21
10.5 TX FIFO ACCESS ...................................................................................................................................... 21
10.6 PATABLE ACCESS ................................................................................................................................... 21
11
MICROCONTROLLER INTERFACE AND PIN CONFIGURATION .......................................... 22
11.1 CONFIGURATION INTERFACE ..................................................................................................................... 22
11.2 GENERAL CONTROL AND STATUS PINS ..................................................................................................... 22
12
DATA RATE PROGRAMMING.......................................................................................................... 23
13
PACKET HANDLING HARDWARE SUPPORT .............................................................................. 24
13.1 PACKET FORMAT ....................................................................................................................................... 24
13.2 PACKET HANDLING ................................................................................................................................... 25
13.3 PACKET HANDLING IN FIRMWARE ............................................................................................................. 26
14
MODULATION FORMATS ................................................................................................................. 26
14.1 FREQUENCY SHIFT KEYING ....................................................................................................................... 26
14.2 AMPLITUDE MODULATION ........................................................................................................................ 27
15
RADIO CONTROL ................................................................................................................................ 27
15.1 POWER-ON START-UP SEQUENCE ............................................................................................................. 28
15.2 CRYSTAL CONTROL ................................................................................................................................... 29
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CC115L
15.3
15.4
15.5
16
17
18
18.1
19
20
21
22
22.1
22.2
23
23.1
23.2
23.3
23.4
23.5
23.6
24
24.1
24.2
24.3
25
26
27
27.1
VOLTAGE REGULATOR CONTROL.............................................................................................................. 29
TRANSMIT MODE (TX) .............................................................................................................................. 29
TIMING ...................................................................................................................................................... 30
TX FIFO .................................................................................................................................................. 31
FREQUENCY PROGRAMMING ........................................................................................................ 31
VCO ......................................................................................................................................................... 32
VCO AND PLL SELF-CALIBRATION .......................................................................................................... 32
VOLTAGE REGULATORS ................................................................................................................. 32
OUTPUT POWER PROGRAMMING ................................................................................................ 33
GENERAL PURPOSE / TEST OUTPUT CONTROL PINS ............................................................. 34
ASYNCHRONOUS AND SYNCHRONOUS SERIAL OPERATION .............................................. 36
ASYNCHRONOUS SERIAL OPERATION ........................................................................................................ 36
SYNCHRONOUS SERIAL OPERATION .......................................................................................................... 36
SYSTEM CONSIDERATIONS AND GUIDELINES ......................................................................... 36
SRD REGULATIONS ................................................................................................................................... 36
CALIBRATION IN MULTI-CHANNEL SYSTEMS ............................................................................................ 37
WIDEBAND MODULATION WHEN NOT USING SPREAD SPECTRUM ............................................................. 37
DATA BURST TRANSMISSIONS................................................................................................................... 37
CONTINUOUS TRANSMISSIONS .................................................................................................................. 38
INCREASING OUTPUT POWER .................................................................................................................... 38
CONFIGURATION REGISTERS ........................................................................................................ 38
CONFIGURATION REGISTER DETAILS - REGISTERS WITH PRESERVED VALUES IN SLEEP STATE ............... 42
CONFIGURATION REGISTER DETAILS - REGISTERS THAT LOOSE PROGRAMMING IN SLEEP STATE .......... 50
STATUS REGISTER DETAILS....................................................................................................................... 50
DEVELOPMENT KIT ORDERING INFORMATION ..................................................................... 52
REFERENCES ....................................................................................................................................... 53
GENERAL INFORMATION ................................................................................................................ 54
DOCUMENT HISTORY ................................................................................................................................ 54
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CC115L
1
Absolute Maximum Ratings
Under no circumstances must the absolute maximum ratings given in Table 1 be violated. Stress
exceeding one or more of the limiting values may cause permanent damage to the device.
Parameter
Min
Max
Supply voltage
–0.3
3.9
V
Voltage on any digital pin
–0.3
VDD + 0.3,
max 3.9
V
Voltage on the pins RF_P, RF_N,
DCOUPL, RBIAS
–0.3
2.0
V
Voltage ramp-up rate
120
kV/µs
Input RF level
+10
dBm
150
C
Solder reflow temperature
260
C
According to IPC/JEDEC J-STD-020
ESD
750
V
According to JEDEC STD 22, method A114, Human
Body Model (HBM)
ESD
400
V
According to JEDEC STD 22, C101C, Charged
Device Model (CDM)
–50
Storage temperature range
Units Condition
All supply pins must have the same voltage
Table 1: Absolute Maximum Ratings
Caution! ESD sensitive device. Precaution should be
used when handling the device in order to prevent
permanent damage.
2 Operating Conditions
The operating conditions for CC115L are listed Table 2 in below.
Parameter
Min
Max
Unit
Operating temperature
−40
85
C
Operating supply voltage
1.8
3.6
V
Condition
All supply pins must have the same voltage
Table 2: Operating Conditions
3 General Characteristics
Parameter
Min
Max
Unit
Frequency range
300
348
MHz
387
464
MHz
779
928
MHz
0.6
500
kBaud
2-FSK
0.6
250
kBaud
GFSK and OOK
0.6
300
kBaud
4-FSK (the data rate in kbps will be twice the baud rate)
Data rate
Condition/Note
If using a 27 MHz crystal, the lower frequency limit for this band
is 392 MHz
Optional Manchester encoding (the data rate in kbps will be half
the baud rate)
Table 3: General Characteristics
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4 Electrical Specifications
4.1
Current Consumption
TA = 25 C, VDD = 3.0 V if nothing else stated. All measurement results are obtained using [1] and [2].
Parameter
Current consumption in
power down modes
Current consumption
Current consumption,
315 MHz
Current consumption,
433 MHz
Current consumption,
868/915 MHz
Min
Typ
Max
Unit
Condition
0.2
1
A
Voltage regulator to digital part off, register values retained (SLEEP
state). All GDO pins programmed to 0x2F (HW to 0)
100
A
Voltage regulator to digital part off, register values retained, XOSC
running (SLEEP state with MCSM0.OSC_FORCE_ON set)
165
A
Voltage regulator to digital part on, all other modules in power down
(XOFF state)
1.7
mA
Only voltage regulator to digital part and crystal oscillator running
(IDLE state)
8.4
mA
Only the frequency synthesizer is running (FSTXON state). This
current consumption is also representative for the other intermediate
states when going from IDLE to TX, including the calibration state
27.4
mA
Transmit mode, +10 dBm output power
15.0
mA
Transmit mode, 0 dBm output power
12.3
mA
Transmit mode, –6 dBm output power
29.2
mA
Transmit mode, +10 dBm output power
16.0
mA
Transmit mode, 0 dBm output power
13.1
mA
Transmit mode, –6 dBm output power
34.2
mA
Transmit mode, +12 dBm output power, 868 MHz
30.0
mA
Transmit mode, +10 dBm output power, 868 MHz
16.8
mA
Transmit mode, 0 dBm output power, 868 MHz
16.4
mA
Transmit mode, –6 dBm output power, 868 MHz.
33.4
mA
Transmit mode, +11 dBm output power, 915 MHz
30.7
mA
Transmit mode, +10 dBm output power, 915 MHz
17.2
mA
Transmit mode, 0 dBm output power, 915 MHz
17.0
mA
Transmit mode, –6 dBm output power, 915 MHz
Table 4: Current Consumption
Supply Voltage
VDD = 1.8 V
Supply Voltage
VDD = 3.0 V
Supply Voltage
VDD = 3.6 V
Temperature [°C]
−40
25
85
−40
25
85
−40
25
85
Current [mA], PATABLE=0xC0, +12 dBm
32.7
31.5
30.5
35.3
34.2
33.3
35.5
34.4
33.5
Current [mA], PATABLE=0xC5, +10 dBm
30.1
29.2
28.3
30.9
30.0
29.4
31.1
30.3
29.6
Current [mA], PATABLE=0x50, 0 dBm
16.4
16.0
15.6
17.3
16.8
16.4
17.6
17.1
16.7
Table 5: Typical TX Current Consumption over Temperature and Supply Voltage, 868 MHz
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Supply Voltage
VDD = 1.8 V
Supply Voltage
VDD = 3.0 V
Supply Voltage
VDD = 3.6 V
Temperature [°C]
−40
25
85
−40
25
85
−40
25
85
Current [mA], PATABLE=0xC0, +11 dBm
31.9
30.7
29.8
34.6
33.4
32.5
34.8
33.6
32.7
Current [mA], PATABLE=0xC3, +10 dBm
30.9
29.8
28.9
31.7
30.7
30.0
31.9
31.0
30.2
Current [mA], PATABLE=0x8E, 0 dBm
17.2
16.8
16.4
17.6
17.2
16.9
17.8
17.4
17.1
Table 6: Typical TX Current Consumption over Temperature and Supply Voltage, 915 MHz
4.2
RF Transmit Section
TA = 25 C, VDD = 3.0 V, +10 dBm if nothing else stated. All measurement results are obtained using [1] and [2].
Parameter
Min
Typ
Max
Unit
Differential load
impedance
Condition/Note
Differential impedance as seen from the RF-port (RF_P and
RF_N) towards the antenna.
315 MHz
122 + j31
433 MHz
116 + j41
868/915 MHz
86.5 + j43
Output power,
highest setting
315 MHz
+10
dBm
433 MHz
+10
dBm
868 MHz
+12
dBm
915 MHz
+11
dBm
Output power,
lowest setting
−30
dBm
Output power is programmable, and full range is available in
all frequency bands. Output power may be restricted by
regulatory limits. See also Design Note DN013 [7], which
gives the output power and harmonics when using multi-layer
inductors. The output power is then typically +10 dBm when
operating at 868/915 MHz.
Delivered to a 50 single-ended load via the RF matching
network in [1] and [2]
Output power is programmable, and full range is available in
all frequency bands
Delivered to a 50 single-ended load via the RF matching
network in [1] and [2]
Measured on [1] and [2] with CW, maximum output power
Harmonics, radiated
2nd Harm, 433 MHz
3rd Harm, 433 MHz
−49
−40
dBm
dBm
2nd Harm, 868 MHz
3rd Harm, 868 MHz
−47
−55
dBm
dBm
2nd Harm, 915 MHz
3rd Harm, 915 MHz
−50
−54
dBm
dBm
Harmonics,
conducted
The antennas used during the radiated measurements
(SMAFF-433 from R.W. Badland and Nearson
S331 868/915) play a part in attenuating the harmonics
Note: All harmonics are below –41.2 dBm when operating in
the 902 - 928 MHz band
Measured with +10 dBm CW at 315 MHz and 433 MHz
315 MHz
< −35
< −53
dBm
dBm
Frequencies below 960 MHz
Frequencies above 960 MHz
433 MHz
−43
< −45
dBm
dBm
Frequencies below 1 GHz
Frequencies above 1 GHz
868 MHz
2nd Harm
other harmonics
−36
< −46
dBm
dBm
Measured with +12 dBm CW at 868 MHz
−34
dBm
Measured with +11 dBm CW at 915 MHz (requirement is
−20 dBc under FCC 15.247)
< −50
dBm
915 MHz
2nd Harm
other harmonics
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Parameter
Min
Typ
Max
Unit
Condition/Note
Spurious emissions
conducted,
harmonics not
included
315 MHz
< −58
< −53
dBm
dBm
Measured with +10 dBm CW at 315 MHz and 433 MHz
Frequencies below 960 MHz
Frequencies above 960 MHz
433 MHz
< −50
< −54
< −56
dBm
dBm
dBm
Frequencies below 1 GHz
Frequencies above 1 GHz
Frequencies within 47-74, 87.5-118, 174-230, 470-862 MHz
868 MHz
< −50
< −52
< −53
dBm
dBm
dBm
Measured with +12 dBm CW at 868 MHz
Frequencies below 1 GHz
Frequencies above 1 GHz
Frequencies within 47-74, 87.5-118, 174-230, 470-862 MHz
All radiated spurious emissions are within the limits of ETSI.
The peak conducted spurious emission is −53 dBm at
699 MHz (868 MHz - 169 MHz), which is in a frequency band
limited to −54 dBm by EN 300 220 V2.3.1. An alternative filter
can be used to reduce the emission at 699 MHz below −54
dBm, for conducted measurements, and is shown in Figure 4.
See more information in DN017 [5].
For compliance with modulation bandwidth requirements
under EN 300 220 V2.3.1 in the 863 to 870 MHz frequency
range it is recommended to use a 26 MHz crystal for
frequencies below 869 MHz and a 27 MHz crystal for
frequencies above 869 MHz.
915 MHz
TX latency
< −51
< −54
dBm
dBm
8
bit
Measured with +11 dBm CW at 915 MHz
Frequencies below 960 MHz
Frequencies above 960 MHz
Serial operation. Time from sampling the data on the
transmitter data input pin until it is observed on the RF output
ports
Table 7: RF Transmit Section
Supply Voltage
VDD = 1.8 V
Supply Voltage
VDD = 3.0 V
Supply Voltage
VDD = 3.6 V
Temperature [°C]
−40
25
85
−40
25
85
−40
25
85
Output Power [dBm], PATABLE=0xC0, +12 dBm
12
11
10
12
12
11
12
12
11
Output Power [dBm], PATABLE=0xC5, +10 dBm
11
10
9
11
10
10
11
10
10
Output Power [dBm], PATABLE=0x50, 0 dBm
1
0
-1
2
1
0
2
1
0
Table 8: Typical Variation in Output Power over Temperature and Supply Voltage, 868 MHz
Supply Voltage
VDD = 1.8 V
Supply Voltage
VDD = 3.0 V
Supply Voltage
VDD = 3.6 V
Temperature [°C]
−40
25
85
−40
25
85
−40
25
85
Output Power [dBm], PATABLE=0xC0, +11 dBm
11
10
10
12
11
11
12
11
11
Output Power [dBm], PATABLE=0x8E, +0 dBm
2
1
0
2
1
0
2
1
0
Table 9: Typical Variation in Output Power over Temperature and Supply Voltage, 915 MHz
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CC115L
4.3
Crystal Oscillator
TA = 25 C, VDD = 3.0 V if nothing else is stated. All measurement results obtained using [1] and [2].
Parameter
Min
Typ
Max
Unit
Condition/Note
Crystal frequency
26
26
27
MHz
For compliance with modulation bandwidth requirements under
EN 300 220 V2.3.1 in the 863 to 870 MHz frequency range it is
recommended to use a 26 MHz crystal for frequencies below 869
MHz and a 27 MHz crystal for frequencies above 869 MHz.
ppm
This is the total tolerance including a) initial tolerance, b) crystal
loading, c) aging, and d) temperature dependence. The
acceptable crystal tolerance depends on RF frequency and
channel spacing / bandwidth.
Tolerance
Load capacitance
±40
10
13
20
ESR
pF
Simulated over operating conditions
µs
This parameter is to a large degree crystal dependent. Measured
on [1] and [2] using crystal AT-41CD2 from NDK
100
Start-up time
150
Table 10: Crystal Oscillator Parameters
4.4
Frequency Synthesizer Characteristics
TA = 25 C, VDD = 3.0 V if nothing else is stated. All measurement results are obtained using [1] and [2]. Min figures are given
using a 27 MHz crystal. Typ. and max figures are given using a 26 MHz crystal.
Parameter
Min
Typ
Max
Unit
Programmed frequency
resolution
397
FXOSC/2
412
Hz
16
Condition/Note
26 - 27 MHz crystal. The resolution (in Hz) is equal
for all frequency bands
Synthesizer frequency
tolerance
±40
ppm
Given by crystal used. Required accuracy
(including temperature and aging) depends on
frequency band and channel bandwidth / spacing
RF carrier phase noise
–92
dBc/Hz
@ 50 kHz offset from carrier
RF carrier phase noise
–92
dBc/Hz
@ 100 kHz offset from carrier
RF carrier phase noise
–92
dBc/Hz
@ 200 kHz offset from carrier
RF carrier phase noise
–98
dBc/Hz
@ 500 kHz offset from carrier
RF carrier phase noise
–107
dBc/Hz
@ 1 MHz offset from carrier
RF carrier phase noise
–113
dBc/Hz
@ 2 MHz offset from carrier
RF carrier phase noise
–119
dBc/Hz
@ 5 MHz offset from carrier
RF carrier phase noise
–129
dBc/Hz
@ 10 MHz offset from carrier
PLL turn-on time
( See Table 20)
72
75
75
s
Time from leaving the IDLE state until arriving in
the FSTXON or TX state, when not performing
calibration. Crystal oscillator running.
PLL calibration time
(See Table 21)
685
712
724
s
Calibration can be initiated manually or
automatically before entering or after leaving TX
Table 11: Frequency Synthesizer Parameters
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4.5
DC Characteristics
TA = 25 C if nothing else stated.
Digital Inputs/Outputs
Min
Max
Unit
Logic "0" input voltage
0
0.7
V
Condition
Logic "1" input voltage
VDD – 0.7
VDD
V
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
–50
nA
Input equals 0 V
Logic "1" input current
N/A
50
nA
Input equals VDD
Table 12: DC Characteristics
4.6
Power-On Reset
For proper Power-On-Reset functionality the power supply should comply with the requirements in
Table 13 below. Otherwise, the chip should be assumed to have unknown state until transmitting an
SRES strobe over the SPI interface. See Section 15.1 on page 28 for further details.
Parameter
Min
Typ
Max
Unit
Condition/Note
5
ms
From 0 V until reaching 1.8 V
ms
Minimum time between power-on and power-off
Power-up ramp-up time
Power off time
1
Table 13: Power-On Reset Requirements
5 Pin Configuration
GND
RBIAS
DGUARD
SI
GND
The CC115L pin-out is shown in Figure 1 and Table 14. See Section 21 for details on the I/O
configuration.
20 19 18 17 16
SCLK 1
15 AVDD
SO (GDO1) 2
14 AVDD
GDO2 3
13 RF_N
DVDD 4
12 RF_P
DCOUPL 5
11 AVDD
9 10
XOSC_Q2
XOSC_Q1
8
AVDD
7
CSn
GDO0
6
GND
Exposed die
attach pad
Figure 1: Pinout Top View
Note: The exposed die attach pad must be connected to a solid ground plane as this is the main
ground connection for the chip
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Pin #
Pin Name
Pin type
Description
1
SCLK
Digital Input
Serial configuration interface, clock input
2
SO (GDO1)
Digital Output
Serial configuration interface, data output
Optional general output pin when CSn is high
3
GDO2
Digital Output
Digital output pin for general use:
Test signals
TX FIFO status signals
Clock output, down-divided from XOSC
4
DVDD
Power (Digital)
1.8 - 3.6 V digital power supply for digital I/O‟s and for the digital core voltage
regulator
5
DCOUPL
Power (Digital)
1.6 - 2.0 V digital power supply output for decoupling
NOTE: This pin is intended for use with the CC115L only. It cannot be used to
provide supply voltage to other devices
6
GDO0
Digital I/O
Digital output pin for general use:
Test signals
TX FIFO status signals
Clock output, down-divided from XOSC
Serial input TX data
7
CSn
Digital Input
Serial configuration interface, chip select
8
XOSC_Q1
Analog I/O
Crystal oscillator pin 1, or external clock input
9
AVDD
Power (Analog)
1.8 - 3.6 V analog power supply connection
10
XOSC_Q2
Analog I/O
Crystal oscillator pin 2
11
AVDD
Power (Analog)
1.8 - 3.6 V analog power supply connection
12
RF_P
RF I/O
Positive RF output signal from PA in transmit mode
13
RF_N
RF I/O
Negative RF output signal from PA in transmit mode
14
AVDD
Power (Analog)
1.8 - 3.6 V analog power supply connection
15
AVDD
Power (Analog)
1.8 - 3.6 V analog power supply connection
16
GND
Ground (Analog)
Analog ground connection
17
RBIAS
Analog I/O
External bias resistor for reference current
18
DGUARD
Power (Digital)
Power supply connection for digital noise isolation
19
GND
Ground (Digital)
Ground connection for digital noise isolation
20
SI
Digital Input
Serial configuration interface, data input
Table 14: Pinout Overview
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CC115L
6 Circuit Description
BIAS
XOSC
RBIAS
XOSC_Q1 XOSC_Q2
DIGITAL INTERFACE TO MCU
PA
TX FIFO
RF_N
FREQ
SYNTH
PACKET HANDLER
RF_P
MODULATOR
RADIO CONTROL
SCLK
SO (GDO1)
SI
CSn
GDO0
GDO2
Figure 2: CC115L Simplified Block Diagram
A simplified block diagram of CC115L is shown
in Figure 2.
reference frequency for the synthesizer, as
well as clocks for the digital part.
The CC115L transmitter is based on direct
synthesis of the RF frequency. The frequency
synthesizer includes a completely on-chip LC
VCO.
A 4-wire SPI serial interface is used for
configuration and data buffer access.
A crystal is to be connected to XOSC_Q1 and
XOSC_Q2. The crystal oscillator generates the
The digital baseband includes support for
channel configuration, packet handling, and
data buffering.
7 Application Circuit
The low cost application circuits ([10] and
[11]), which use multi layer inductors, are
shown in Figure 3 and Figure 4 (see Table 15
for component values).
The designs in [1] and [2] were used for CC115L
characterization. The 315 MHz and 433 MHz
design [1] use inexpensive multi-layer
inductors similar to the low cost application
circuit while the 868 MHz and 915 MHz design
[2] use wire-wound inductors. Wire-wound
inductors give better output power and
7.1
attenuation of harmonics compared to using
multi-layer inductors.
Refer to design note DN032 [9] for information
about performance when using wire-wound
inductors from different vendors. See also
Design Note DN013 [7], which gives the output
power and harmonics when using multi-layer
inductors. The output power is then typically
+10
dBm
when
operating
at
868/915 MHz.
Bias Resistor
The 56 kΩ bias resistor R171 is used to set an
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CC115L
7.2
Balun and RF Matching
The balun and LC filter component values
their placement are important to keep
performance optimized. Gerber files
schematics for the reference designs
available for download from the TI website
and
the
and
are
The components between the RF_N/RF_P
pins and the point where the two signals are
joined together (C131, C122, L122, and L132
in Figure 3 and L121, L131, C121, L122,
C131, C122, and L132 in Figure 4) form a
balun that converts the differential RF signal
on CC115L to a single-ended RF signal. C124 is
needed for DC blocking.
1.8 V - 3.6 V
power supply
L123, L124, and C123 ( plus C125 in Figure 3)
form a low-pass filter for harmonics
attenuation.
The balun and LC filter components also
matches the CC115L input impedance to a 50
load. C126 provides DC blocking and is only
needed if there is a DC path in the antenna.
For the application circuit in Figure 4, this
component may also be used for additional
filtering, see section 7.5.
R171
1 SCLK
2 SO
(GDO1)
3 GDO2
GND 16
RBIAS 17
DGUARD 18
SI 20
SO
(GDO1)
GDO2
(optional)
AVDD 14
C131
L132
C126
RF_N 13
DIE ATTACH PAD:
9 AVDD
7 CSn
5 DCOUPL
10 XOSC_Q2
RF_P 12
8 XOSC_Q1
4 DVDD
C51
Antenna
(50 Ohm)
AVDD 15
CC115L
6 GDO0
Digital Inteface
SCLK
GND 19
SI
AVDD 11
C122
L122
L123
L124
C123
C125
C124
GDO0
(optional)
CSn
XTAL
C81
C101
Figure 3: Typical Application and Evaluation Circuit 315/433 MHz
(excluding supply decoupling capacitors)
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CC115L
1.8 V - 3.6 V
power supply
R171
4 DVDD
GND 16
AVDD 14
L132
L131
C126
RF_N 13
L123
AVDD 11
L124
C121 C122
DIE ATTACH PAD: RF_P 12
7 CSn
C51
AVDD 15
CC115L
5 DCOUPL
Antenna
(50 Ohm)
C131
10 XOSC_Q2
3 GDO2
9 AVDD
2 SO
(GDO1)
RBIAS 17
GND 19
1 SCLK
8 XOSC_Q1
SO
(GDO1)
GDO2
(optional)
6 GDO0
Digital Interface
SCLK
DGUARD 18
SI 20
SI
L121
C123
L122
GDO0
(optional)
CSn
C127 L125
C127 and L125
may be added to
build an optional
filter to reduce
emission at 699
MHz
C124
XTAL
C81
C101
Figure 4: Typical Application and Evaluation Circuit 868/915 MHz
(excluding supply decoupling capacitors)
Component
Value at 315 MHz
Value at 433 MHz
C121
Value at 868/915 MHz
Without C127 and L125
With C127 and L125
1 pF
1 pF
C122
6.8 pF
3.9 pF
1.5 pF
1.5 pF
C123
12 pF
8.2 pF
3.3 pF
3.3 pF
C124
220 pF
220 pF
100 pF
100 pF
C125
6.8 pF
5.6 pF
C126
220 pF
220 pF
100 pF
12 pF
C127
C131
47 pF
6.8 pF
3.9 pF
L121
1.5 pF
1.5 pF
12 nH
12 nH
L122
33 nH
27 nH
18 nH
18 nH
L123
18 nH
22 nH
12 nH
12 nH
L124
33 nH
27 nH
12 nH
12 nH
L125
3.3 nH
L131
L132
33 nH
27 nH
12 nH
12 nH
18 nH
18 nH
Table 15: External Components
7.3
Crystal
A crystal in the frequency range 26 - 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 (C81 and C101)
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capacitor values depend on the total load
capacitance, CL, specified for the crystal. The
total load capacitance seen between the
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CC115L
crystal terminals should equal CL for the
crystal to oscillate at the specified frequency.
CL
1
1
C81
1
C101
C parasitic
The parasitic capacitance is constituted by pin
input capacitance and PCB stray capacitance.
Total parasitic capacitance is typically 2.5 pF.
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
7.4
For compliance with modulation bandwidth
requirements under EN 300 220 V2.3.1 in the
863 to 870 MHz frequency range it is
recommended to use a 26 MHz crystal for
frequencies below 869 MHz and a 27 MHz
crystal for frequencies above 869 MHz.
connected to XOSC_Q1 using a serial
capacitor. When using a full-swing digital
signal, this capacitor can be omitted. The
XOSC_Q2 line must be left un-connected. C81
and C101 can be omitted when using a
reference signal.
If this filtering is not necessary, C126 will work
as a DC block (only necessary if there is a DC
path in the antenna). C127 and L125 should in
that case be left unmounted.
Additional external components (e.g. an RF
SAW filter) may be used in order to improve
the performance in specific applications.
Power Supply Decoupling
The power supply must be properly decoupled
close to the supply pins. Note that decoupling
capacitors are not shown in the application
circuit. The placement and the size of the
7.7
Avoid routing digital signals with sharp edges
close to XOSC_Q1 PCB track or underneath
the crystal Q1 pad as this may shift the crystal
dc operating point and result in duty cycle
variation.
Additional Filtering
In the 868/915 MHz reference design [10],
C127 and L125 together with C126 build an
optional filter to reduce emission at carrier
frequency - 169 MHz. This filter is necessary
for applications with an external antenna
connector that seek compliance with ETSI EN
300 220 V2.3.1. For more information, see
DN017 [5].
7.6
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.
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 fullswing digital signal (0 V to VDD) or a sine
wave of maximum 1 V peak-peak amplitude.
The reference signal must be connected to the
XOSC_Q1 input. The sine wave must be
7.5
order to ensure a reliable start-up (see Section
4.3 on page 9).
decoupling capacitors are very important to
achieve the optimum performance ([10] and
[11] should be followed closely).
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.
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In [10] and [11] 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
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CC115L
100%. See Figure 5 for top solder resist and
top paste masks.
Each decoupling capacitor 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 CC115L supply pin. Supply power filtering is
very important.
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 the chip or the balun/RF matching
circuit, or between the chip‟s ground vias and
the decoupling capacitor‟s ground vias should
be avoided. This improves the grounding and
ensures the shortest possible current return
path.
Avoid routing digital signals with sharp edges
close to XOSC_Q1 PCB track or underneath
the crystal Q1 pad as this may shift the crystal
dc operating point and result in duty cycle
variation.
The external components should ideally be as
small as possible (0402 is recommended) and
surface
mount
devices
are
highly
recommended. Please note that components
with different sizes 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.
A CC11xL Development Kit with a fully
assembled CC115L Evaluation Module is
available. It is strongly advised that this
reference layout is followed very closely in
order to get the best performance. The
schematic, BOM and layout Gerber files are all
available from the TI website ([10] and [11]).
Figure 5: Left: Top Solder Resist Mask (Negative). Right: Top Paste Mask. Circles are Vias
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CC115L
8 Configuration Overview
CC115L can be configured to achieve optimum
RF output power
Data buffering with the 64-byte TX FIFO
Packet radio hardware support
performance for many different applications.
Configuration is done using the SPI interface.
See Section 10 for more description of the SPI
interface. The following key parameters can be
programmed:
Details of each configuration register can be
found in Section 24, starting on page 38.
Figure 6 shows a simplified state diagram that
explains the main CC115L states together with
typical usage and current consumption. For
detailed information on controlling the CC115L
state machine, and a complete state diagram,
see Section 15, starting on page 28.
Power-down / power up mode
Crystal oscillator power-up / power-down
Carrier frequency / RF channel
Transmit mode
Data rate
Modulation format
Lowest power mode. Most
register values are retained.
Typ. current consumption:
200 nA
Sleep
SPWD
SIDLE
Default state when the radio is not
transmitting. Typ. current
consumption: 1.7 mA.
Used for calibrating frequency
synthesizer upfront (entering
Manual freq.
transmit mode can then be
synth. calibration
done quicker). Transitional
state. Typ. current
consumption: 8.4 mA.
Frequency synthesizer is on,
ready to start transmitting.
Transmission starts very
quickly after receiving the STX
command strobe.Typ. current
consumption: 8.4 mA.
CSn=0
IDLE
SXOFF
SCAL
CSn=0
STX or SFSTXON
Frequency
synthesizer startup,
optional calibration,
settling
SFSTXON
All register values are
retained. Typ. current
consumption: 165 uA.
Crystal
oscillator off
Frequency synthesizer is turned on, can optionally be
calibrated, and then settles to the correct frequency.
Transitional state. Typ. current consumption: 8.4 mA.
Frequency
synthesizer on
STX
STX
TXOFF_MODE=01
Typ. current consumption:
16.8 mA at 0 dBm output
power, 868 MHz
Transmit mode
TXOFF_MODE=00
In Normal mode, this state is
enetered if the TX FIFO is emptied
before the complete packet has
been written to the FIFO.
Typ. current consumption: 1.7 mA.
TX FIFO
underflow
Optional transitional state.
Optional freq.
Typ. current consumption: 8.4 mA. synth. calibration
SFTX
IDLE
Figure 6: Simplified Radio Control State Diagram with Typical Current Consumption
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CC115L
9 Configuration Software
CC115L
After chip reset, all the registers have default
values as shown in the tables in Section 24.1.
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.
can be configured using the
SmartRF Studio software [4]. The SmartRF
Studio software is highly recommended for
obtaining optimum register settings, and for
evaluating performance and functionality.
10 4-wire Serial Configuration and Data Interface
CC115L is configured via a simple 4-wire SPI-
from/to a register, the transfer will be
cancelled. The timing for the address and data
transfer on the SPI interface is shown in
Figure 7 with reference to Table 16.
compatible interface (SI, SO, SCLK and CSn)
where CC115L is the slave. This interface is also
used to write buffered data. All transfers on the
SPI interface are done most significant bit first.
When CSn is pulled low, the MCU must wait
until CC115L SO pin goes low before starting to
transfer the header byte. This indicates that
the crystal is running. Unless the chip was in
the SLEEP or XOFF states, the SO pin will
always go low immediately after pulling CSn
low.
All transactions on the SPI interface start with
a header byte containing a R/W
¯ bit, a burst
access bit (B), and a 6-bit address (A5 - A0).
The CSn pin must be kept low during transfers
on the SPI bus. If CSn goes high during the
transfer of a header byte or during read/write
tsp
tch
tcl
tsd
thd
tns
SCLK:
CSn:
Write to register:
SI
X
0
B
A5
A4
A3
A2
A1
A0
SO
Hi-Z
S7
B
S5
S4
S3
S2
S1
S0
X
DW7
S7
DW6
DW5
DW4
DW3
DW2
DW1
DW0
S6
S5
S4
S3
S2
S1
S0
DR2
DR1
X
Hi-Z
Read from register:
SI
X
SO Hi-Z
1
B
A5
A4
A3
A2
A1
A0
S7
B
S5
S4
S3
S2
S1
S0
X
DR7
DR6
DR5
DR4
DR3
DR0
Hi-Z
Figure 7: Configuration Registers Write and Read Operations
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CC115L
Parameter
Description
Min
Max
Units
fSCLK
SCLK frequency
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
MHz
SCLK frequency, single access. No delay between address and data byte
-
9
SCLK frequency, burst access
No delay between address and data byte, or between data bytes
-
6.5
tsp,pd
CSn low to positive edge on SCLK, in power-down mode
150
-
s
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
-
40
ns
tfall
Clock fall time
tsd
Setup data (negative SCLK edge) to positive edge on SCLK
(tsd applies between address and data bytes, and between data bytes)
-
40
ns
Single access
55
-
ns
Burst access
76
-
thd
Hold data after positive edge on SCLK
20
-
ns
tns
Negative edge on SCLK to CSn high.
20
-
ns
Table 16: SPI Interface Timing Requirements
Note: The minimum tsp,pd figure in Table 16 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 powerdown depends on the start-up time of the crystal being used. The 150 μs in Table 16 is the
crystal oscillator start-up time measured on [1] and [2] using crystal AT-41CD2 from NDK.
10.1 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 CC115L on the SO pin.
The status byte contains key status signals,
useful for the MCU. The first bit, s7, is the
CHIP_RDYn signal and this signal must go low
before the first positive edge of SCLK. The
CHIP_RDYn signal indicates that the crystal is
running.
Bits 6, 5, and 4 comprise the STATE value.
This value reflects the state of the chip. The
XOSC and power to the digital core are on in
the IDLE state, but all other modules are in
power down. The frequency and channel
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configuration should only be updated when the
chip is in this state.
The last four bits (3:0) in the status byte
contains FIFO_BYTES_AVAILABLE. For
these bits to give any valid information, the
R/W
¯ bit in the header byte must be set to 0.
The FIFO_BYTES_AVAILABLE field will then
contain the number of bytes that can be
written
to
the
TX
FIFO.
When
FIFO_BYTES_AVAILABLE=15, 15 or more
bytes can be written.
Table 17 gives a status byte summary
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CC115L
Bits
Name
Description
7
CHIP_RDYn
Stays high until power and crystal have stabilized. Should always be low when using
the SPI interface.
6:4
STATE[2:0]
Indicates the current main state machine mode
3:0
FIFO_BYTES_AVAILABLE[3:0]
Value
State
Description
000
IDLE
IDLE state
(Also reported for some transitional states
instead of SETTLING or CALIBRATE)
001
Reserved
010
TX
Transmit mode
011
FSTXON
Fast TX ready
100
CALIBRATE
Frequency synthesizer calibration is running
101
SETTLING
PLL is settling
110
Reserved
111
TXFIFO_UNDERFLOW
TX FIFO has underflowed. Acknowledge with
SFTX
The number of bytes that can be written to the TX FIFO
Table 17: Status Byte Summary
10.2 Register Access
The configuration registers on the CC115L are
located on SPI addresses from 0x00 to 0x2E.
Table 29 on page 40 lists all configuration
registers. It is highly recommended to use
SmartRF Studio [4] to generate optimum
register settings. The detailed description of
each register is found in Section 24.1 and
24.2, starting on page 42. All configuration
registers can be both written to and read. The
R/W
¯ bit controls if the register should be
written to 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 (B) in the header byte. The address
bits (A5 - A0) set 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 - 0x3D, the burst bit is used to select
between status registers when burst bit is one,
and command strobes when burst bit is zero.
See more in Section 10.3 below. Because of
this, burst access is not available for status
registers and they must be accessed one at a
time. The status registers can only be read.
10.3 SPI Read
When reading register fields over the SPI
interface while the register fields are updated
by the radio hardware (e.g. MARCSTATE or
TXBYTES), there is a small, but finite,
probability that a single read from the register
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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 CC115L Errata Notes [3] for more details.
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CC115L
10.4 Command Strobes
Command Strobes may be viewed as single
byte instructions to CC115L. By addressing a
command strobe register, internal sequences
will be started. These commands are used to
disable the crystal oscillator, enable TX mode,
enable calibration etc. The 9 command
strobes are listed in Table 28 on page 39.
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
by transferring a single header byte (no data is
being transferred). That is, only the R/W
¯ bit,
the burst access bit (set to 0), and the six
address bits (in the range 0x30 through 0x3D)
are written. The R/W
¯ bit should be set to zero
if the FIFO_BYTES_AVAILABLE field in the
status byte should be interpreted.
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 strobe is being issued,
one will have to wait for SO to go low again
before the next header byte can be issued as
shown in Figure 8. The command strobes are
executed immediately, with the exception of
the SPWD and the SXOFF strobes, which are
executed when CSn goes high.
CSn
SO
HeaderSRES
SI
HeaderAddr
Data
Figure 8: SRES Command Strobe
10.5 TX FIFO Access
The 64-byte TX FIFO is accessed through the
0x3F address. The TX FIFO is write-only and
the R/W
¯ bit should therefore be zero.
The burst bit is used to determine if the
TX FIFO access is a single byte access or a
burst access. The single byte access method
expects a header byte with the burst bit set to
zero and one data byte. After the data byte, a
new header byte is expected; hence CSn can
remain low. The burst access method expects
one header byte and then consecutive data
bytes until terminating the access by setting
CSn high.
The following
TX FIFO:
header
bytes
access
the
0x3F: Single byte access to TX FIFO
0x7F: Burst access to TX FIFO
When writing to the TX FIFO, the status byte
(see Section 10.1) is output on SO for each
new data byte as shown in Figure 7. This
status byte can be used to detect TX FIFO
underflow while writing data to the TX FIFO.
Note that 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 on SI,
the status byte received concurrently on SO
will indicate that one byte is free in
the TX FIFO.
The TX FIFO may be flushed by issuing a
SFTX command strobe. A SFTX command
strobe can only be issued in the IDLE, or
TXFIFO_UNDERFLOW states. The TX FIFO
is flushed when going to the SLEEP state.
Figure 9 gives a brief overview of different
register access types possible.
10.6 PATABLE Access
The 0x3E address is used to access the
PATABLE, which is used for selecting PA
power control settings. The SPI expects one or
two data bytes after receiving the address (the
burst bit must be set if two bytes are to be
written). For OOK, two bytes should be written
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to PATABLE; the first byte after the address will
set the logic 0 power level and the second
byte written will set the logic 1 power level. For
all other modulations formats, only one byte
should be written to PATABLE. Use SmartRF
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CC115L
Studio [4] or DN013 [7] for recommended
register values for a given output power.
The PATABLE can also be read by setting the
R/W
¯ bit to 1. The read operation can be done
as a single byte or burst access, depending on
how many bytes should be read (one or two).
Note that pulling CSn high will reset the index
counter to zero, meaning that burst access
needs to be used for reading/writing the
second PATABLE entry. For the same reason,
if one byte is written to the PATABLE and this
value is to be read out, CSn must be set high
before the read access in order to set the
index counter back to zero.
Note that the content of the PATABLE is lost
when entering the SLEEP state, except for the
first byte, meaning that if OOK is used, the
PATABLE needs to be reprogrammed when
waking up from SLEEP.
Csn
Command strobe(s)
HeaderStrobe
HeaderStrobe
HeaderStrobe
Read or write register(s)
HeaderReg
Data
HeaderReg
Data
Read or write
consecutive register(s)
HeaderReg n
Datan
Data n + 1
Datan + 2
Write n + 1 bytes to the
TX FIFO
HeaderTX FIFO
DataByte 0
DataByte 1
DataByte 2
.........
DataByte n - 1
DataByte n
HeaderReg
Data
HeaderStrobe
HeaderReg
Data
HeaderStrobe
HeaderTX FIFO
Combinations
HeaderReg
Data
.........
.........
.........
DataByte 0
DataByte 1
....
Figure 9: Register Access Types
11 Microcontroller Interface and Pin Configuration
In a typical system, CC115L will interface to a
microcontroller. This microcontroller must be
able to:
Program CC115L into different modes
Write buffered data
Read back status information via the 4-wire
SPI-bus configuration interface (SI, SO,
SCLK and CSn)
11.1 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 10 on
page 18.
11.2 General Control and Status Pins
The CC115L has two dedicated configurable
pins (GDO0 and GDO2) and one shared pin
(GDO1) that can output internal status
information useful for control software. These
pins can be used to generate interrupts on the
MCU. See Section 21 on page 34 for more
details on the signals that can be
programmed.
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GDO1 is shared with 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.
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CC115L
12 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 the formula shows, the programmed
data rate depends on the crystal frequency.
RDATA
(256 DRATE _ M ) 2 DRATE _ E
f XOSC
2 28
The following approach can be used to find
suitable values for a given data rate:
DRATE _ E
log2
RDATA 220
f XOSC
according to Table 18 below. See Table 3 for
the minimum and maximum data rates for the
different modulation formats.
Min Data
Rate
[kBaud]
Typical
Data Rate
[kBaud]
Max Data
Rate
[kBaud]
Data rate
Step Size
[kBaud]
0.6
1.0
0.79
0.0015
0.79
1.2
1.58
0.0031
1.59
2.4
3.17
0.0062
3.17
4.8
6.33
0.0124
6.35
9.6
12.7
0.0248
12.7
19.6
25.3
0.0496
25.4
38.4
50.7
0.0992
50.8
76.8
101.4
0.1984
101.6
153.6
202.8
0.3967
203.1
250
405.5
0.7935
406.3
500
500
1.5869
28
DRATE _ M
RDATA 2
f XOSC 2 DRATE _ E
256
If DRATE_M is rounded to the nearest integer
and becomes 256, increment DRATE_E and
use DRATE_M = 0.
Table 18: Data Rate Step Size
(assuming a 26 MHz crystal)
The data rate can be set from 0.6 kBaud to
500 kBaud with the minimum step size
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13 Packet Handling Hardware Support
The CC115L has built-in hardware support for
packet oriented radio protocols.
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 (sync) word.
Can be duplicated to give a 4-byte sync
word. It is not possible to only insert
preamble or only insert a sync word
A CRC checksum computed over the data
field.
In a system where the CC115L is
transmitting packets to the CC110L, CC113L
or CC1101, the recommended setting is 4byte 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 CC115L is in the IDLE state.
13.1 Packet Format
The format of the data packet can be
configured and consists of the following items
(see Figure 10):
Preamble
Synchronization word
Optional length byte
Optional address byte
Payload
Optional 2 byte CRC
Legend:
Data field
16/32 bits
8
bits
8
bits
8 x n bits
Inserted automatically
CRC-16
Address field
8 x n bits
Length field
Preamble bits
(1010...1010)
Sync word
Optional CRC-16 calculation
OptIonal user-provided fields (the length field is
processed by the radio)
Unprocessed user data
16 bits
Figure 10: Packet Format
The preamble pattern is an alternating
sequence of ones and zeros (10101010…).
The minimum length of the preamble is
programmable
through
the
value
of
MDMCFG1.NUM_PREAMBLE. 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. If the
CC110L, CC113L, or CC1101 are used at the
receiving end, they will need the sync word for
byte synchronization of the incoming packet.
The synchronization word is automatically
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inserted by the CC115L. A one-byte sync 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 setting
MDMCFG2.SYNC_MODE
to 3. The sync word will then be repeated
twice.
CC115L supports both constant packet length
protocols and variable 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. This value must be different from 0.
In
variable
packet
length
mode,
PKTCTRL0.LENGTH_CONFIG=1, the packet
length is configured by the first byte
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CC115L
transmitted after the sync word. The packet
length is defined as the payload data,
excluding the length byte and the optional
CRC. The PKTLEN value must be different
from 0
With PKTCTRL0.LENGTH_CONFIG=2, the
packet length is set to infinite and transmission
will continue until turned off manually. As
described in the next section, this can be used
to support packet formats with different length
configuration than natively supported by
CC115L. One should make sure that TX mode is
not turned off during the transmission of the
first half of any byte. Refer to the CC115L Errata
Notes [3] for more details.
Note: The minimum packet length
supported (excluding the optional length
byte and CRC) is one byte of payload
data.
13.1.1 Packet Length > 255
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 packet
length mode
(PKTCTRL0.LENGTH_CONFIG=2) must be
active and the PKTLEN register is set to
mod(length, 256). When less than 256 bytes
remains of the packet, the MCU disables
infinite packet length mode and activates fixed
packet
length
mode
(PKTCTRL0.LENGTH_CONFIG=0). When the
internal byte counter reaches the PKTLEN
value, the transmission ends (the radio enters
the state determined by TXOFF_MODE).
Automatic CRC appending/checking can also
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 11)
Set PKTCTRL0.LENGTH_CONFIG=2.
Pre-program the PKTLEN
mod(600, 256) = 88.
register to
Transmit at least 345 bytes (600 - 255), 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.
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 mode enabled
Length field transmitted. PKTLEN set to
mod(600, 256) = 88
Fixed packet length mode anbled when
less than 256 bytes remains of packet
600 bytes transmitted
Figure 11: Packet Length > 255
13.2 Packet Handling
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 the receiver is
the CC110L, CC113L, or CC1101, and address
recognition is enabled, the second byte written
to the TX FIFO must be the address byte.
If fixed packet length is enabled, the first byte
written to the TX FIFO should be the address
(assuming the receiver uses address
recognition).
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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 followed
by 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 following 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.
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CC115L
13.3 Packet Handling in Firmware
IOCFGx.GDOx_CFG=0x03). See Table 27
for more information.
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:
b) SPI Polling
The PKTSTATUS register can be polled at a
given rate to get information about the current
GDO2 and GDO0 values. 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.
a) Interrupt Driven Solution
The GDO pins can be used 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 are in the TX FIFO
(IOCFGx.GDOx_CFG=0x02 and
It is recommended to employ an interrupt
driven solution due to 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 (see Section 10.3 and the CC115L
Errata Notes [3]).
14 Modulation Formats
CC115L supports amplitude, frequency, and
the
modulator
by
MDMCFG2.MANCHESTER_EN=1.
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
setting
Note: Manchester encoding is not
supported at the same time as using 4-FSK
modulation.
14.1 Frequency Shift Keying
CC115L supports 2-(G)FSK and 4-FSK
modulation. When selecting 4-FSK, the
preamble and sync word is sent using 2-FSK
(see Figure 12).
The symbol encoding is shown in Table 19.
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:
f dev
f xosc
(8 DEVIATION _ M ) 2 DEVIATION _ E
217
1/Baud Rate
Format
Symbol
Coding
2-FSK/GFSK
„0‟
– Deviation
„1‟
+ Deviation
4-FSK
„01‟
– Deviation
„00‟
– 1/3∙Deviation
„10‟
+1/3∙Deviation
„11‟
+ Deviation
Table 19: Symbol Encoding for 2-FSK/GFSK
and 4-FSK Modulation
1/Baud Rate
1/Baud Rate
+1
+1/3
-1/3
-1
1
0
1
0
1
0
1
0
Preamble
0xAA
1
1
0
1
0
0
Sync
0xD3
1
1
00 01 01 11 10 00 11 01
Data
0x17 0x8D
Figure 12: Data Sent Over the Air (MDMCFG2.MOD_FORMAT=100)
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CC115L
14.2 Amplitude Modulation
The amplitude modulation supported by CC115L
is On-Off Keying (OOK). OOK modulation
simply turns the PA on or off to modulate ones
and zeros respectively.
The DEVIATN register setting has no effect
when using OOK.
15 Radio Control
SIDLE
SLEEP
0
SPWD
CAL_COMPLETE
MANCAL
3,4,5
CSn = 0
IDLE
1
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 13: Complete Radio Control State Diagram
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CC115L
CC115L has a built-in state machine that is used
to switch between different operational 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 6 on page 17. The complete
radio control state diagram is shown in
Figure 13. The numbers refer to the state
number readable in the MARCSTATE status
register. This register is primarily for test
purposes.
15.1 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 below, i.e.
automatic power-on reset (POR) 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.
However, to optimize performance in TX, an
alternative GDO setting from the settings
found in Table 27 on page 35 should be
selected.
15.1.2 Manual Reset
The other global reset possibility on CC115L
uses the SRES command strobe. By issuing
this strobe, all internal registers and states are
set to the default, IDLE state. The manual
power-up sequence is as follows (see Figure
15):
Set SCLK = 1 and SI = 0.
Strobe CSn low / high.
Hold CSn low and then high for at least
40 µs relative to pulling CSn low
Pull CSn low and wait for SO to go low
(CHIP_RDYn).
15.1.1 Automatic POR
A power-on reset circuit is included in the
CC115L. The minimum requirements stated in
Table 13 must be followed for the power-on
reset to function properly. The internal powerup 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 CC115L reset is completed, the chip
will be in the IDLE state and the crystal
oscillator will be running. If the chip has had
sufficient time for the crystal oscillator to
stabilize after the power-on-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 is not stabilized, before going
low as shown in Figure 14.
Issue the SRES strobe on the SI line.
When SO goes low again, reset is
complete and the chip is in the IDLE state.
XOSC and voltage regulator switched on
40 us
CSn
SO
XOSC Stable
SI
SRES
Figure 15: Power-On Reset with SRES
CSn
SO
XOSC Stable
Note that the above reset procedure is
only required just after the power supply is
first turned on. If the user wants to reset
the CC115L after this, it is only necessary to
issue an SRES command strobe.
Figure 14: Power-On Reset
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15.2 Crystal Control
The crystal oscillator (XOSC) is either
automatically controlled or always on, if
MCSM0.XOSC_FORCE_ON is set.
In the automatic mode, the XOSC 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 the 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 10.1 on
page 19.
If the XOSC is forced on, the crystal will
always stay on even in the SLEEP state.
Crystal oscillator start-up time depends on
crystal ESR and load capacitances. The
electrical specification for the crystal oscillator
can be found in Section 4.3 on page 9.
15.3 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.
15.4 Transmit Mode (TX)
Transmit mode is activated directly by the
MCU by using the STX command strobe.
The frequency synthesizer must be calibrated
regularly. CC115L has one manual calibration
option (using the SCAL strobe), and three
automatic calibration options that are
controlled by the MCSM0.FS_AUTOCAL setting:
Calibrate when going from IDLE to TX
or FSTXON
Calibrate when going from TX to IDLE
1
automatically
Calibrate every fourth time when going
3
from TX to IDLE automatically
If the radio goes from TX to IDLE by issuing an
SIDLE strobe, calibration will not be
1
Not forced in IDLE by issuing an SIDLE
strobe
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performed. The calibration takes a constant
number of XOSC cycles; see Table 20 for
timing details regarding calibration.
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 preamble
The SIDLE command strobe can always be
used to force the radio controller to go to the
IDLE state.
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15.5 Timing
The value of the TEST0, TEST1, and
FSCAL3 registers
15.5.1 Overall State Transition Times
The main radio controller needs to wait in
certain states in order to make sure that the
internal analog/digital parts have settled down
and are ready to operate in the new states. A
number of factors are important for the state
transition times:
The crystal oscillator frequency, fxosc
OOK used or not
Table 20 shows timing in crystal clock cycles
for key state transitions.
Note that the TX to IDLE transition time is a
function of data rate (fbaudrate). When OOK is
used (i.e. FREND0.PA_POWER=001b), TX to
IDLE will require 1/8∙fbaudrate longer times than
the time stated in Table 20.
The data rate in cases where OOK is
used
Description
Transition Time (FREND0.PA_POWER=0)
Transition Time [µs]
IDLE to TX/FSTXON, no calibration
1954/fxosc
75.2
IDLE to TX/FSTXON, with calibration
1953/fxosc + FS calibration Time
799
TX to IDLE, no calibration
~0.25/fbaudrate
~1
TX to IDLE, with calibration
~0.25/fbaudrate + FS calibration Time
725
Manual calibration
283/fxosc + FS calibration Time
735
Table 20: Overall State Transition Times (Example for 26 MHz crystal oscillator, 250 kBaud data
rate, and TEST0 = 0x0B (maximum calibration time)).
15.5.2 Frequency
Time
Synthesizer
Calibration
Table
21
summarizes
the
frequency
synthesizer (FS) calibration times for possible
settings
of
TEST0
and
FSCAL3.CHP_CURR_CAL_EN.
Setting
FSCAL3.CHP_CURR_CAL_EN to 00b disables
the charge pump calibration stage. TEST0 is
set to the values recommended by SmartRF
Studio software [4]. The possible values for
TEST0 when operating with different frequency
bands are 0x09 and 0x0B. The SmartRF
Studio
software
[4]
always
sets
FSCAL3.CHP_CURR_CAL_EN to 10b.
The calibration time can be reduced from
712/724 µs to 145/157 µs. See Section 23.2
on page 37 for more details.
TEST0
FSCAL3.CHP_CURR_CAL_EN
FS Calibration Time
fxosc = 26 MHz
FS Calibration Time
fxosc = 27 MHz
0x09
00b
3764/fxosc = 145 µs
3764/fxosc = 139 µs
0x09
10b
18506/fxosc = 712 µs
18506/fxosc = 685 µs
0x0B
00b
4073/fxosc = 157 µs
4073/fxosc = 151 µs
0x0B
10b
18815/fxosc = 724 µs
18815/fxosc = 697 µs
Table 21. Frequency Synthesizer Calibration Times (26/27 MHz crystal)
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16 TX FIFO
The CC115L contains a 64-byte TX FIFO for
data to be transmitted and the SPI interface is
used to write to the TX FIFO (see Section 10.5
for more details). The FIFO controller will
detect underflow in the TX FIFO.
A signal will assert when the number of bytes
in the TX FIFO is equal to or higher than the
programmed threshold. This signal can be
viewed on the GDO pins (see Table 27 on
page 35).
When writing to the TX FIFO it is the
responsibility of the MCU to avoid TX FIFO
overflow. A TX FIFO overflow will result in an
error in the TX FIFO content.
Figure 16 shows the number of bytes in the
TX FIFO when the threshold signal toggles in
the case of FIFO_THR=13. Figure 17 shows
the signal on the GDO pin as the TX FIFO is
filled above the threshold, and then drained
below in the case of FIFO_THR=13.
The chip status byte that is available on the
SO pin while transferring the SPI header
contains the fill grade of the TX FIFO
(R/W
¯ = 0). Section 10.1 on page 19 contains
more details on this.
The number of bytes in the TX FIFO can also
be
read
from
the
status
register
TXBYTES.NUM_TXBYTES.
The 4-bit FIFOTHR.FIFO_THR setting is used
to program threshold points in the TX FIFO.
Table 22 lists the 16 FIFO_THR settings and
the corresponding thresholds for the TX FIFO.
FIFO_THR=13
FIFO_THR
Bytes in
TX FIFO
0 (0000)
61
1 (0001)
57
2 (0010)
53
3 (0011)
49
4 (0100)
45
5 (0101)
41
6 (0110)
37
NUM_TXBYTES
7 (0111)
33
GDO
8 (1000)
29
9 (1001)
25
10 (1010)
21
11 (1011)
17
12 (1100)
13
13 (1101)
9
14 (1110)
5
15 (1111)
1
Underflow
margin
8 bytes
TX FIFO
Figure 16 Example of TX FIFO at Threshold
6
7
8
9
10
9
8
7
6
Figure 17: Number of Bytes in TX FIFO vs.
the GDO Signal
(GDOx_CFG=0x02 and FIFO_THR=13)
Table 22: FIFO_THR Settings and the
Corresponding TX FIFO Thresholds
17 Frequency Programming
The frequency programming in CC115L is
designed to minimize the programming
needed when changing frequency.
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
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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,
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CC115L
CHANNR.CHAN, which is multiplied by the
channel offset. The resultant carrier frequency
f carrier
is given by:
f XOSC
( FREQ CHAN ((256 CHANSPC _ M ) 2CHANSPC _ E 2 ))
16
2
With a 26 MHz crystal the maximum channel
spacing is 405 kHz. To get e.g. 1 MHz channel
spacing, one solution is to use 333 kHz
channel spacing and select each third channel
in CHANNR.CHAN.
The preferred IF frequency is programmed
with the FSCTRL1.FREQ_IF register. The IF
frequency is given by:
f IF
f XOSC
FREQ _ IF
210
If any frequency programming register is
altered when the frequency synthesizer is
running, the synthesizer may give an
undesired response. Hence, the frequency
should only be updated when the radio is in
the IDLE state
18 VCO
The VCO is completely integrated on-chip.
18.1 VCO and PLL Self-Calibration
The VCO characteristics vary with temperature
and supply voltage changes as well as with
the desired operating frequency. In order to
ensure reliable operation, CC115L includes
frequency synthesizer self-calibration 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 20 on
page 30.
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 automatically. 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.
Note:
The
calibration
values
are
maintained in SLEEP mode, so the
calibration is still valid after waking up from
SLEEP mode unless supply voltage or
temperature has changed significantly.
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. Refer
also to the CC115L Errata Notes [3].
For more robust operation, the source code
could include a check so that the PLL is recalibrated until PLL lock is achieved if the PLL
does not lock the first time.
19 Voltage Regulators
CC115L contains several on-chip linear voltage
regulators that generate the supply voltages
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 Table 1 and Table 14
are not exceeded.
By setting the CSn pin low, the voltage
regulator to the digital core turns on and the
crystal oscillator starts. The SO pin on the SPI
interface must go low before the first positive
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edge of SCLK (setup time is given in
Table 16).
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 CC115L.
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CC115L
20 Output Power Programming
The RF output power level from the device has
two levels of programmability. The PATABLE
register can hold two user selected output
power settings and the FREND0.PA_POWER
value selects the PATABLE entry to use (0 or
1). PATABLE must be programmed in burst
mode if writing to other entries than
PATABLE[0].See Section 10.6 on page 21
for more programming details.
Table 25 contains recommended PATABLE
settings for various output levels and
frequency bands. DN013 [7] gives the
complete tables for the different frequency
bands using multi-layer inductors. Using PA
settings from 0x61 to 0x6F is not allowed.
Table 26 contains output power and current
consumption for default PATABLE setting
(0xC6). The measurements are done on ([2]).
For OOK modulation, FREND0.PA_POWER
should be 1 and the logic 0 and logic 1 power
levels shall be programmed to index 0 and 1
respectively. For all other modulation formats,
the desired output power should be
programmed to index 0.
Note: All content of the PATABLE except
for the first byte (index 0) is lost when
entering the SLEEP state.
868 MHz
915 MHz
Output Power [dBm]
Setting
Current Consumption,
Typ. [mA]
Setting
Current Consumption,
Typ. [mA]
12/11
0xC0
34.2
0xC0
33.4
10
0xC5
30.0
0xC3
30.7
7
0xCD
25.8
0xCC
25.7
5
0x86
19.9
0x84
20.2
0
0x50
16.8
0x8E
17.2
−6
0x37
16.4
0x38
17.0
−10
0x26
14.5
0x27
14.8
−15
0x1D
13.3
0x1E
13.3
−20
0x17
12.6
0x0E
12.5
−30
0x03
12.0
0x03
11.9
Table 23: Optimum PATABLE Settings for Various Output Power Levels Using Wire-Wound
Inductors in 868/915 MHz Frequency Bands
868 MHz
915 MHz
Default Power
Setting
Output Power
[dBm]
Current
Consumption,
Typ. [mA]
Output Power
[dBm]
Current
Consumption,
Typ. [mA]
0xC6
9.6
29.4
8.9
28.7
Table 24: Output Power and Current Consumption for Default PATABLE Setting Using WireWound Inductors in 868/915 MHz Frequency Bands
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868 MHz
915 MHz
Output Power [dBm]
Setting
Current
Consumption,
Typ. [mA]
Setting
Current
Consumption,
Typ. [mA]
10
0xC2
32.4
0xC0
31.8
7
0xCB
26.8
0xC7
26.9
5
0x81
21.0
0xCD
24.3
0
0x50
16.9
0x8E
16.7
-10
0x27
15.0
0x27
14.9
-15
0x1E
13.4
0x1E
13.4
-20
0x0F
12.7
0x0E
12.6
-30
0x03
12.1
0x03
12.0
Table 25: Optimum PATABLE Settings for Various Output Power Levels Using Multi-layer
Inductors in 868/915 MHz Frequency Bands
868 MHz
915 MHz
Default Power
Setting
Output Power
[dBm]
Current
Consumption,
Typ. [mA]
Output Power
[dBm]
Current
Consumption,
Typ. [mA]
0xC6
8.5
29.5
7.2
27.4
Table 26: Output Power and Current Consumption for Default PATABLE Setting Using Multi-layer
Inductors in 868/915 MHz Frequency Bands
21 General Purpose / Test Output Control Pins
The three digital output pins GDO0, GDO1, and
GDO2 are general control pins configured with
IOCFG0.GDO0_CFG, IOCFG1.GDO1_CFG, and
IOCFG2.GDO2_CFG respectively. Table 27 shows
the different signals that can be monitored on the
GDO pins. These signals can be used as inputs to
the MCU.
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.
If the IOCFGx.GDOx_CFG setting is less than
0x20 and IOCFGx_GDOx_INV is 0 (1), the
GDO0 and GDO2 pins will be hardwired to 0 (1),
GDO1 is the same pin as the SO pin on the SPI and the GDO1 pin will be hardwired to 1 (0) in
interface, thus the output programmed on this pin the SLEEP state. These signals will be
will only be valid when CSn is high. The default hardwired until the CHIP_RDYn signal goes low.
value for GDO1 is 3-stated which is useful when
If the IOCFGx.GDOx_CFG setting is 0x20 or
the SPI interface is shared with other devices.
higher, the GDO pins will work as programmed
The
default
value
for
GDO0
is
a also in SLEEP state. As an example, GDO1 is
135 - 141 kHz clock output (XOSC frequency high
impedance
in
all
states
if
divided by 192). Since the XOSC is turned on at IOCFG1.GDO1_CFG=0x2E.
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GDOx_CFG[5:0]
Description
0 (0x00) - 1 (0x01)
Reserved - used for test.
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 - used for test.
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. The pin will deassert if the TX FIFO underflows.
7 (0x07) - 9 (0x09)
Reserved - used for test.
10 (0x0A)
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.
11 (0x0B)
Serial Clock. Synchronous to the data in synchronous serial mode.
Data is sampled by CC115L on the rising edge of the serial clock when GDOx_INV=0.
12 (0x0C)
Serial Synchronous Data Output. Used for synchronous serial mode.
13 (0x0D)
Serial Data Output. Used for asynchronous serial mode.
14 (0x0E) - 26 (0x1A)
Reserved - used for test.
27 (0x1B)
PA_PD. Note: PA_PD will have the same signal level in SLEEP and TX states. To control an external
PA in applications where the SLEEP state is used it is recommended to use GDOx_CFGx=0x2F
instead.
28 (0x1C) - 40 (0x28)
Reserved - used for test.
41 (0x29)
CHIP_RDYn.
42 (0x2A)
Reserved - used for test.
43 (0x2B)
XOSC_STABLE.
44 (0x2C) - 45 (0x2D)
Reserved - used for test.
46 (0x2E)
High impedance (3-state).
47 (0x2F)
HW to 0 (HW1 achieved by setting GDOx_INV=1). Can be used to control an external PA
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
Note: There are 3 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 two GDO pins 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.
Table 27: GDOx Signal Selection (x = 0, 1, or 2)
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22 Asynchronous and Synchronous Serial Operation
Several features and modes of operation have
been included in the CC115L to provide
backward compatibility with previous Chipcon
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.
22.1 Asynchronous Serial Operation
Asynchronous transfer is included in the
CC115L for backward compatibility with systems
that are already using the asynchronous data
transfer.
When asynchronous transfer is enabled, all
packet handling support is disabled and it is
not possible to use Manchester encoding.
Asynchronous serial mode is enabled by
setting PKTCTRL0.PKT_FORMAT
to 3.
Strobing STX will configure the GDO0 pin as
data input (TX data) regardless of the content
of the IOCFG0 register.
The CC115L 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.
22.2 Synchronous Serial Operation
Setting
PKTCTRL0.PKT_FORMAT
to
1
enables synchronous serial mode. When using
this mode, sync detection should be disabled
together
with
CRC
calculation
(MDMCFG2.SYNC_MODE=000
and
PKTCTRL0.CRC_EN=0).
Infinite
packet
length
mode
should
be
used
(PKTCTRL0.LENGTH_CONFIG=10b).
In synchronous serial mode, data is
transferred on a two-wire serial interface. The
CC115L provides a clock that is used to set up
new data on the data input line. Data input (TX
data) is on the GDO0 pin. This pin will
automatically be configured as an input when
TX is active. The TX latency is 8 bits.
The MCU must handle preamble and sync
word insertion in software, together with CRC
calculation and insertion.
23 System Considerations and Guidelines
23.1 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, 433 MHz, 868 MHz,
or 915 MHz frequency bands. The CC115L is
specifically designed for such use with its
300 - 348 MHz, 387 - 464 MHz, and
779 - 928 MHz operating ranges. The most
important regulations when using the CC115L in
the 315 MHz, 433 MHz, 868 MHz, or 915 MHz
frequency bands are EN 300 220 V2.3.1
(Europe) and FCC CFR47 part 15 (USA).
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For compliance with modulation bandwidth
requirements under EN 300 220 V2.3.1 in the
863 to 870 MHz frequency range it is
recommended to use a 26 MHz crystal for
frequencies below 869 MHz and a 27 MHz
crystal for frequencies above 869 MHz.
Please note that compliance with regulations
is dependent on the complete system
performance. It is the customer‟s responsibility
to ensure that the system complies with
regulations.
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23.2 Calibration in Multi-Channel Systems
CC115L is highly suited for multi-channel
systems due to its agile frequency synthesizer
and effective communication interface.
Charge pump current, VCO current, and VCO
capacitance array calibration data is required
for each frequency when implementing a multichannel system. There are 3 ways of obtaining
the calibration data from the chip:
1) Calibration for every frequency change. The
PLL calibration time is 712/724 µs (26 MHz
crystal and TEST0 = 0x09/0B, see Table 21).
The blanking interval between each frequency
is then 787/799 µs.
2) Perform all necessary calibration at startup
and store 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 change, 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 75 µs
(Table 20). The blanking interval between
each frequency hop is then approximately
75 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. 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 712/724 µs to 145/157 µs
(26 MHz crystal and TEST0 = 0x09/0B, see
Table 21). The blanking interval between each
frequency hop is then 220/232 µs.
There is a trade-off between blanking time and
memory space needed for storing calibration
data in non-volatile 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 567 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 [4] to get the correct
settings for a specific frequency before doing a
calibration, regardless of which calibration
method is being used.
Note: The content in the TEST0 register is
not retained in SLEEP state, thus it is
necessary to re-write this register when
returning from the SLEEP state.
23.3 Wideband Modulation when not Using Spread Spectrum
Digital modulation systems under FCC part
15.247 include 2-FSK, GFSK, and 4-FSK
modulation. A maximum peak output power of
1 W (+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
separation, the CC115L is suited for systems
targeting compliance with digital modulation
system as defined by FCC part 15.247. An
external power amplifier such as CC1190 [8] is
needed to increase the output above +11
dBm. Please refer to DN006 [6] for further
details concerning wideband modulation and
CC115L.
23.4 Data Burst Transmissions
The high maximum data rate of CC115L opens
up for burst transmissions. A low average data
rate link (e.g. 10 kBaud) can be realized by
using a higher over-the-air data rate. Buffering
the data and transmitting in bursts at high data
rate (e.g. 500 kBaud) will reduce the time in
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current consumption significantly. Reducing
the time in TX mode will reduce the likelihood
of collisions with other systems in the same
frequency range.
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23.5 Continuous Transmissions
In data streaming applications, the CC115L
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 radios often prevents this kind of
continuous data streaming and reduces the
effective data rate).
23.6 Increasing Output Power
The PA portion of the CC1190 [8] can be used
together with CC115L in applications
where increased output power is needed.
24 Configuration Registers
The configuration of CC115L is done by
programming 8-bit registers. The optimum
configuration data based on selected system
parameters are most easily found by using the
SmartRF Studio software [4]. Complete
descriptions of the registers are given in the
following tables. 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 28. Accessing these registers will initiate
the change of an internal state or mode. There
are 34 normal 8-bit configuration registers
listed in Table 29, and SmartRF Studio [4] will
provide recommended settings for these
2
registers .
There are also 5 status registers that are listed
in Table 30. These registers, which are readonly, contain information about the status of
CC115L.
The TX FIFO is accessed through one 8-bit
register. During the header byte transfer and
while writing data to a register or the TX FIFO,
a status byte is returned on the SO line. This
status byte is described in Table 17 on page
20.
Table 31 summarizes the SPI address space.
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.
value to them. Addresses marked as
“Reserved” must be configured according to
SmartRF Studio[4].
2
Addresses marked as “Not Used” can be part
of a burst access and one can write a dummy
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Address
Strobe Name
Description
0x30
SRES
Reset chip.
0x31
SFSTXON
Enable and calibrate frequency synthesizer (if MCSM0.FS_AUTOCAL=1).
0x32
SXOFF
Turn off crystal oscillator.
0x33
SCAL
Calibrate frequency synthesizer and turn it off. SCAL can be strobed from IDLE mode
without setting manual calibration mode (MCSM0.FS_AUTOCAL=0)
0x34
Reserved
0x35
STX
In IDLE state: Enable TX. Perform calibration first if MCSM0.FS_AUTOCAL=1.
0x36
SIDLE
Enter IDLE state
0x37 - 0x38
Reserved
0x39
SPWD
0x3A
Reserved
0x3B
SFTX
0x3C
Reserved
0x3D
SNOP
Enter power down mode when CSn goes high.
Flush the TX FIFO buffer. Only issue SFTX in IDLE or TXFIFO_UNDERFLOW states.
No operation. May be used to get access to the chip status byte.
Table 28: Command Strobes
Address
Register
Description
Preserved in
SLEEP State
Details on
Page Number
0x00
IOCFG2
Yes
42
0x01
IOCFG1
Yes
42
0x02
IOCFG0
GDO2 output pin configuration
GDO1 output pin configuration
GDO0 output pin configuration
Yes
42
0x03
FIFOTHR
TX FIFO threshold
Yes
43
0x04
SYNC1
Sync word, high byte
Yes
43
0x05
SYNC0
Sync word, low byte
Yes
43
0x06
PKTLEN
Packet length
Yes
43
0x07
Not Used
Packet automation control
Yes
44
Channel number
Yes
44
0x08
PKTCTRL0
0x09
Not Used
0x0A
CHANNR
0x0B
Not Used
0x0C
FSCTRL0
Frequency synthesizer control
Yes
44
0x0D
FREQ2
Frequency control word, high byte
Yes
44
0x0E
FREQ1
Frequency control word, middle byte
Yes
45
0x0F
FREQ0
Frequency control word, low byte
Yes
45
0x10
MDMCFG4
Modem configuration
Yes
45
0x11
MDMCFG3
Modem configuration
Yes
45
0x12
MDMCFG2
Modem configuration
Yes
46
0x13
MDMCFG1
Modem configuration
Yes
46
0x14
MDMCFG0
Modem configuration
Yes
47
0x15
DEVIATN
Modem deviation setting
Yes
47
0x16
Not Used
0x17
MCSM1
Main Radio Control State Machine Configuration
Yes
47
0x18
MCSM0
Main Radio Control State Machine configuration
Yes
48
0x19 - 0x1F
Not Used
0x20
Reserved
0x21
Not Used
0x22
FREND0
Front end TX configuration
Yes
49
0x23
FSCAL3
Frequency synthesizer calibration
Yes
49
0x24
FSCAL2
Frequency synthesizer calibration
Yes
49
48
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Address
Register
Description
Preserved in
SLEEP State
Details on
Page Number
0x25
FSCAL1
Frequency synthesizer calibration
Yes
49
0x26
FSCAL0
Frequency synthesizer calibration
Yes
49
0x27 - 0x28
Not Used
0x29 - 0x2B
RESERVED
No
50
0x2C
TEST2
Various test settings
No
50
0x2D
TEST1
Various test settings
No
50
0x2E
TEST0
Various test settings
No
50
Table 29: Configuration Registers Overview
Address
Register
Description
Details on Page
Number
0x30 (0xF0)
PARTNUM
Part number for CC115L
50
0x31 (0xF1)
VERSION
Current version number
50
0x32 - 0x34 (0xF2 - 0xF4)
Reserved
0x35 (0xF5)
MARCSTATE
Control state machine state
51
0x36 - 0x37 (0xF6 - 0xF7)
Reserved
0x38 (0xF8)
PKTSTATUS
Current GDOx status and packet status
52
0x39 (0xF9)
Reserved
0x3A (0xFA)
TXBYTES
Underflow and number of bytes in the TX FIFO
52
0x3B - 0x3D (0xFB - 0xFD)
Reserved
Table 30: Status Registers Overview
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SRES
SFSTXON
SXOFF
SCAL
Reserved
STX
SIDLE
Reserved
Reserved
SPWD
Reserved
SFTX
Reserved
SNOP
PATABLE
TX FIFO
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
0x31
0x32
0x33
0x34
0x35
0x36
0x37
0x38
0x39
0x3A
0x3B
0x3C
0x3D
0x3E
0x3F
Read
Single Byte Burst
+0x80
+0xC0
IOCFG2
IOCFG1
IOCFG0
FIFOTHR
SYNC1
SYNC0
PKTLEN
Not Used
PKTCTRL0
Not Used
CHANNR
Not Used
FSCTRL0
FREQ2
FREQ1
FREQ0
MDMCFG4
MDMCFG3
MDMCFG2
MDMCFG1
MDMCFG0
DEVIATN
Not Used
MCSM1
MCSM0
Not Used
Not Used
Not Used
Not Used
Not Used
Not Used
Not Used
Not Used
Not Used
FREND0
FSCAL3
FSCAL2
FSCAL1
FSCAL0
Not Used
Not Used
RESERVED
RESERVED
RESERVED
TEST2
TEST1
TEST0
Not Used
SRES
PARTNUM
SFSTXON VERSION
SXOFF
Reserved
SCAL
Reserved
Reserved Reserved
STX
MARCSTATE
SIDLE
Reserved
Reserved Reserved
Reserved PKTSTATUS
SPWD
Reserved
Reserved TXBYTES
SFTX
Reserved
Reserved Reserved
SNOP
Reserved
PATABLE PATABLE PATABLE
TX FIFO Reserved Reserved
R/W configuration registers, burst access possible
Write
Single Byte Burst
+0x00
+0x40
Table 31: SPI Address Space
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24.1 Configuration Register Details - Registers with preserved values in SLEEP state
0x00: IOCFG2 - GDO2 Output Pin Configuration
Bit
Field Name
Reset
7
R/W
Description
R0
Not used
6
GDO2_INV
0
R/W
Invert output, i.e. select active low (1) / high (0)
5:0
GDO2_CFG[5:0]
41 (101001)
R/W
Default is CHP_RDYn (See Table 27 on page 35).
0x01: IOCFG1 - GDO1 Output Pin Configuration
Bit
Field Name
Reset
R/W
Description
7
GDO_DS
0
R/W
Set high (1) or low (0) output drive strength on the GDO pins.
6
GDO1_INV
0
R/W
Invert output, i.e. select active low (1) / high (0)
5:0
GDO1_CFG[5:0]
46 (101110)
R/W
Default is 3-state (See Table 27 on page 35).
0x02: IOCFG0 - GDO0 Output Pin Configuration
Bit
Field Name
7
Reset
R/W
Description
0
R/W
Use setting from SmartRF Studio [4]
6
GDO0_INV
0
R/W
Invert output, i.e. select active low (1) / high (0)
5:0
GDO0_CFG[5:0]
63 (111111)
R/W
Default is CLK_XOSC/192 (See Table 27 on page 35).
It is recommended to disable the clock output in initialization,
in order to optimize RF performance.
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0x03: FIFOTHR - TX FIFO Thresholds
Bit
Field Name
7:4
3:0
FIFO_THR[3:0]
Reset
R/W
Description
0 (00)
R/W
Use setting from SmartRF Studio [4]
7
(0111)
R/W
Set the threshold for the TX FIFO. The threshold is exceeded when the
number of bytes in the TX FIFO is equal to or higher than the threshold value.
Setting
Bytes in TX FIFO
0 (0000)
61
1 (0001)
57
2 (0010)
53
3 (0011)
49
4 (0100)
45
5 (0101)
41
6 (0110)
37
7 (0111)
33
8 (1000)
29
9 (1001)
25
10 (1010)
21
11 (1011)
17
12 (1100)
13
13 (1101)
9
14 (1110)
5
15 (1111)
1
0x04: SYNC1 - Sync Word, High Byte
Bit
Field Name
Reset
R/W
Description
7:0
SYNC[15:8]
211
(0xD3)
R/W
8 MSB of 16-bit sync word
0x05: SYNC0 - Sync Word, Low Byte
Bit
Field Name
Reset
R/W
Description
7:0
SYNC[7:0]
145
(0x91)
R/W
8 LSB of 16-bit sync word
0x06: PKTLEN - Packet Length
Bit
Field Name
Reset
R/W
Description
7:0
PACKET_LENGTH
255
(0xFF)
R/W
Indicates the packet length when fixed packet length mode is enabled. This
value must be different from 0
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0x08: PKTCTRL0 - Packet Automation Control
Bit
Field Name
Reset
7
6
5:4
PKT_FORMAT[1:0]
3
2
CRC_EN
R/W
Description
R0
Not used
1
R/W
Use setting from SmartRF Studio [4]
0 (00)
R/W
Format of TX data
Setting
Packet format
0 (00)
Normal mode, use TX FIFO
1 (01)
Synchronous serial mode, Data in on GDO0
2 (10)
Random TX mode; sends random data using PN9
generator. Used for test.
3 (11)
Asynchronous serial mode, Data in on GDO0
0
R0
Not used
1
R/W
1: CRC calculation enabled
0: CRC calculation disabled
1:0
LENGTH_CONFIG[1:0]
1 (01)
R/W
Configure the packet length
Setting
Packet length configuration
0 (00)
Fixed packet length mode. Length configured in
PKTLEN register
1 (01)
Variable packet length mode. Packet length configured
by the first byte written to the TX FIFO
2 (10)
Infinite packet length mode
3 (11)
Reserved
0x0A: CHANNR - Channel Number
Bit
Field Name
Reset
R/W
Description
7:0
CHAN[7:0]
0 (0x00)
R/W
The 8-bit unsigned channel number, which is multiplied by the
channel spacing setting and added to the base frequency.
0x0C: FSCTRL0 - Frequency Synthesizer Control
Bit
Field Name
Reset
R/W
Description
7:0
FREQOFF[7:0]
0 (0x00)
R/W
Frequency offset added to the base frequency before being used by
the frequency synthesizer. (2s-complement).
Resolution is FXTAL/214 (1.59kHz-1.65kHz); range is ±202 kHz to
±210 kHz, dependent of XTAL frequency.
0x0D: FREQ2 - Frequency Control Word, High Byte
Bit
Field Name
Reset
R/W
Description
7:6
FREQ[23:22]
0 (00)
R
FREQ[23:22] is always 0 (the FREQ2 register is less than 36 with
26 - 27 MHz crystal)
5:0
FREQ[21:16]
30 (011110)
R/W
FREQ[23:0] is the base frequency for the frequency synthesiser in
increments of fXOSC/216.
f carrier
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FREQ[23 : 0]
216
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0x0E: FREQ1 - Frequency Control Word, Middle Byte
Bit
Field Name
Reset
R/W
Description
7:0
FREQ[15:8]
196 (0xC4)
R/W
Ref. FREQ2 register
0x0F: FREQ0 - Frequency Control Word, Low Byte
Bit
Field Name
Reset
R/W
Description
7:0
FREQ[7:0]
236 (0xEC)
R/W
Ref. FREQ2 register
0x10: MDMCFG4 - Modem Configuration
Bit
Field Name
7:4
3:0
DRATE_E[3:0]
Reset
R/W
Description
8 (1000)
R/W
Use setting from SmartRF Studio [4]
12 (1100)
R/W
The exponent of the user specified symbol rate
0x11: MDMCFG3 - Modem Configuration
Bit
Field Name
Reset
R/W
Description
7:0
DRATE_M[7:0]
34 (0x22)
R/W
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:
RDATA
(256 DRATE _ M ) 2 DRATE _ E
2 28
f XOSC
The default values give a data rate of 115.051 kBaud (closest setting to
115.2 kBaud), assuming a 26.0 MHz crystal.
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0x12: MDMCFG2 - Modem Configuration
Bit
Field Name
7
6:4
MOD_FORMAT[2:0]
Reset
R/W
Description
0
R/W
Use setting from SmartRF Studio [4]
0 (000)
R/W
The modulation format of the radio signal
Setting
Modulation format
0 (000)
2-FSK
1 (001)
GFSK
2 (010)
Reserved
3 (011)
OOK
4 (100)
4-FSK
5 (101)
Reserved
6 (110)
Reserved
7 (111)
Reserved
4-FSK modulation cannot be used together with Manchester
encoding.
3
MANCHESTER_EN
0
R/W
Enables Manchester encoding.
0 = Disable
1 = Enable
Manchester encoding cannot be used when using asynchronous
serial mode or 4-FSK modulation
2:0
SYNC_MODE[2:0]
2 (010)
R/W
Number of sync bits transmitted
Setting
Sync-word qualifier mode
0 (000)
No preamble/sync
1 (001)
16 bits sync word
2 (010)
Reserved
3 (011)
32 bits sync word
4 (100) - 7 (111)
Reserved
0x13: MDMCFG1 - Modem Configuration
Bit
Field Name
7
6:4
NUM_PREAMBLE[2:0]
Reset
R/W
Description
0
R/W
Use setting from SmartRF Studio [4]
2 (010)
R/W
Sets the minimum number of preamble bytes to be transmitted
3:2
1:0
CHANSPC_E[1:0]
2 (10)
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Setting
Number of preamble bytes
0 (000)
2
1 (001)
3
2 (010)
4
3 (011)
6
4 (100)
8
5 (101)
12
6 (110)
16
7 (111)
24
R0
Not used
R/W
2 bit exponent of channel spacing
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0x14: MDMCFG0 - Modem Configuration
Bit
Field Name
Reset
R/W
Description
7:0
CHANSPC_M[7:0]
248 (0xF8)
R/W
8-bit mantissa of channel spacing. The channel spacing is multiplied by
the channel number CHAN and added to the base frequency. It is
unsigned and has the format:
f CHANNEL
f XOSC
(256 CHANSPC _ M ) 2CHANSPC _ E
218
The default values give 199.951 kHz channel spacing (the closest
setting to 200 kHz), assuming 26.0 MHz crystal frequency.
0x15: DEVIATN - Modem Deviation Setting
Bit
Field Name
Reset
7
6:4
DEVIATION_E[2:0]
4 (100)
3
2:0
DEVIATION_M[2:0]
7 (111)
R/W
Description
R0
Not used.
R/W
Deviation exponent.
R0
Not used.
R/W
2-FSK/
GFSK/
4-FSK
Specifies the nominal frequency deviation from the carrier
for
a „0‟ (-DEVIATN) and „1‟ (+DEVIATN) in a mantissaexponent format, interpreted as a 4-bit value with MSB
implicit 1. The resulting frequency deviation is given by:
f dev
f xosc
(8 DEVIATION _ M ) 2 DEVIATION _ E
217
The default values give ±47.607 kHz deviation assuming
26.0 MHz crystal frequency.
OOK
This setting has no effect
0x17: MCSM1 - Main Radio Control State Machine Configuration
Bit
Field Name
Reset
R/W
Description
R0
Not used
3 (1100)
R/W
Use setting from SmartRF Studio [4]
0 (00)
R/W
Select what should happen when a packet has been sent
7:6
5:2
1:0
TXOFF_MODE[1:0]
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Setting
Next state after finishing packet transmission
0 (00)
IDLE
1 (01)
FSTXON
2 (10)
Stay in TX (start sending preamble)
3 (11)
Reserved
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0x18: MCSM0 - Main Radio Control State Machine Configuration
Bit
Field Name
Reset
FS_AUTOCAL[1:0]
0 (00)
7:6
5:4
3:2
PO_TIMEOUT
1 (01)
R/W
Description
R0
Not used
R/W
Automatically calibrate when going to to/from TX mode
R/W
Setting
When to perform automatic calibration
0 (00)
Never (manually calibrate using SCAL strobe)
1 (01)
When going from IDLE to TX or FSTXON
2 (10)
When going from TX back to IDLE
automatically
3 (11)
Every 4th time when going from TX to IDLE
automatically
Programs the number of times the six-bit ripple counter
must expire after the XOSC has settled before CHP_RDYn
goes low. 3
If XOSC is on (stable) during power-down, PO_TIMEOUT
shall be set so that the regulated digital supply voltage has
time to stabilize before CHP_RDYn goes low
(PO_TIMEOUT=2 recommended). Typical start-up time for
the voltage regulator is 50 μs.
For robust operation it is recommended to use
PO_TIMEOUT = 2 or 3 when XOSC is off during powerdown.
Setting
Expire count
Timeout after XOSC start
0 (00)
1
Approx. 2.3 - 2.4 μs
1 (01)
16
Approx. 37 - 39 μs
2 (10)
64
Approx. 149 - 155 μs
3 (11)
256
Approx. 597 - 620 μs
Exact timeout depends on crystal frequency.
1
0
XOSC_FORCE_ON
0
R/W
0
R/W
Force the XOSC to stay on in the SLEEP state.
0x20: RESERVED
Bit
7:3
Field Name
Reset
R/W
Description
31 (11111)
R/W
Use setting from SmartRF Studio [4]
R0
Not used
R/W
See SmartRF Studio [4] for setting
2
1:0
0 (00)
3
Note that the XOSC_STABLE signal will be asserted at the same time as the CHIP_RDYn signal;
i.e. the PO_TIMEOUT delays both signals and does not insert a delay between the signals.
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0x22: FREND0 - Front End TX Configuration
Bit
Field Name
Reset
7:6
5:4
LODIV_BUF_CURRENT_TX[1:0]
1 (01)
3
2:0
PA_POWER[2:0]
0 (000)
R/W
Description
R0
Not used
R/W
Adjusts current TX LO buffer (input to PA). The value to use
in this field is given by the SmartRF Studio software [4].
R0
Not used
R/W
Selects PA power setting. This value is an index to the
PATABLE, which can be programmed with up to 2 different
PA settings. When using OOK, PA_POWER should be 001,
and for all other modulation formats it should be 000. Please
see Sections 10.6 and Section 20 for more details.
0x23: FSCAL3 - Frequency Synthesizer Calibration
Bit
Field Name
Reset
R/W
Description
7:6
FSCAL3[7:6]
2 (10)
R/W
Frequency synthesizer calibration configuration. The value to
write in this field before calibration is given by the
SmartRF Studio software [4].
5:4
CHP_CURR_CAL_EN[1:0]
2 (10)
R/W
Disable charge pump calibration stage when 0.
3:0
FSCAL3[3:0]
9 (1001)
R/W
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
Please see Section 23.2 for more details.
0x24: FSCAL2 - Frequency Synthesizer Calibration
Bit
Field Name
Reset
7:6
R/W
Description
R0
Not used
5
VCO_CORE_H_EN
0
R/W
Choose high (1) / low (0) VCO
4:0
FSCAL2[4:0]
10 (01010)
R/W
Frequency synthesizer calibration result register. VCO current
calibration result and override value.
Please see Section 23.2 for more details.
0x25: FSCAL1 - Frequency Synthesizer Calibration
Bit
Field Name
Reset
7:6
5:0
FSCAL1[5:0]
32 (0x20)
R/W
Description
R0
Not used
R/W
Frequency synthesizer calibration result register. Capacitor
array setting for VCO coarse tuning.
Please see Section 23.2 for more details.
0x26: FSCAL0 - Frequency Synthesizer Calibration
Bit
Field Name
Reset
7
6:0
FSCAL0[6:0]
13 (0x0D)
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R/W
Description
R0
Not used
R/W
Frequency synthesizer calibration control. The value to use in
this register is given by the SmartRF Studio software [4].
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CC115L
24.2 Configuration Register Details - Registers that Loose Programming in SLEEP State
0x29: RESERVED
Bit
Field Name
7:0
Reset
R/W
Description
89 (0x59)
R/W
Use setting from SmartRF Studio [4]
0x2A: RESERVED
Bit
Field Name
7:0
Reset
R/W
Description
127 (0x7F)
R/W
Use setting from SmartRF Studio [4]
0x2B: RESERVED
Bit
Field Name
7:0
Reset
R/W
Description
63 (0x3F)
R/W
Use setting from SmartRF Studio [4]
0x2C: TEST2 - Various Test Settings
Bit
Field Name
Reset
R/W
Description
7:0
TEST2[7:0]
136 (0x88)
R/W
Use setting from SmartRF Studio [4]
0x2D: TEST1 - Various Test Settings
Bit
Field Name
Reset
R/W
Description
7:0
TEST1[7:0]
49 (0x31)
R/W
Use setting from SmartRF Studio [4]
0x2E: TEST0 - Various Test Settings
Bit
Field Name
Reset
R/W
Description
7:2
TEST0[7:2]
2 (000010)
R/W
Use setting from SmartRF Studio [4]
1
VCO_SEL_CAL_EN
1
R/W
Enable VCO selection calibration stage when 1
0
TEST0[0]
1
R/W
Use setting from SmartRF Studio [4]
24.3 Status Register Details
0x30 (0xF0): PARTNUM - Chip ID
Bit
Field Name
Reset
R/W
Description
7:0
PARTNUM[7:0]
0 (0x00)
R
Chip part number
0x31 (0xF1): VERSION - Chip ID
Bit
Field Name
Reset
R/W
Description
7:0
VERSION[7:0]
9 (0x09)
R
Chip version number.
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CC115L
0x35 (0xF5): MARCSTATE - Main Radio Control State Machine State
Bit
Field Name
7:5
4:0
MARC_STATE[4:0]
Reset
R/W
Description
R0
Not used
R
Main Radio Control FSM State
Value
State name
State (Figure 13, page 27)
0 (0x00)
SLEEP
SLEEP
1 (0x01)
IDLE
IDLE
2 (0x02)
XOFF
XOFF
3 (0x03)
VCOON_MC
MANCAL
4 (0x04)
REGON_MC
MANCAL
5 (0x05)
MANCAL
MANCAL
6 (0x06)
VCOON
FS_WAKEUP
7 (0x07)
REGON
FS_WAKEUP
8 (0x08)
STARTCAL
CALIBRATE
9 (0x09)
BWBOOST
SETTLING
10 (0x0A)
FS_LOCK
SETTLING
11 (0x0B)
Reserved
12 (0x0C)
ENDCAL
13 (0x0D)
17 (0x11)
Reserved
18 (0x12)
FSTXON
FSTXON
19 (0x13)
TX
TX
20 (0x14)
TX_END
TX
21 (0x15)
Reserved
22 (0x16)
TXFIFO_UNDERFLOW
CALIBRATE
TXFIFO_UNDERFLOW
Note: 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.
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CC115L
0x38 (0xF8): PKTSTATUS - Current GDOx Status and Packet Status
Bit
Field Name
Reset
7:3
2
GDO2
R/W
Description
R
Reserved
R
Current GDO2 value. Note: the reading gives the non-inverted value
irrespective of what IOCFG2.GDO2_INV is programmed to.
It is not recommended to check for PLL lock by reading
PKTSTATUS[2] with GDO2_CFG=0x0A.
1
0
GDO0
R0
Not used
R
Current GDO0 value. Note: the reading gives the non-inverted value
irrespective of what IOCFG0.GDO0_INV is programmed to.
It is not recommended to check for PLL lock by reading
PKTSTATUS[0] with GDO0_CFG=0x0A.
0x3A (0xFA): TXBYTES - Underflow and Number of Bytes
Bit
Field Name
Reset
R/W
7
TXFIFO_UNDERFLOW
R
6:0
NUM_TXBYTES
R
Description
Number of bytes in TX FIFO
25 Development Kit Ordering Information
Orderable Evaluation Module
Description
Minimum Order Quantity
CC11xLDK-868-915
CC11xL Development Kit, 868/915 MHz
1
CC11xLEMK-433
CC11xL Evaluation Module Kit, 433 MHz
1
Figure 18: Development Kit Ordering Information
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CC115L
26
[1]
References
Characterization Design 315 - 433 MHz
(Identical to the CC1101EM 315 - 433 MHz Reference Design (swrr046.zip))
[2]
Characterization Design 868 - 915 MHz
(Identical to the CC1101EM 868 - 915 MHz Reference Design (swrr045.zip))
[3]
CC115L Errata Notes (swrz036.pdf)
[4]
SmartRF Studio (swrc176.zip)
[5]
DN017 CC11xx 868/915 MHz RF Matching (swra168.pdf)
[6]
DN006 CC11xx Settings for FCC 15.247 Solutions (swra123.pdf)
[7]
DN013 Programming Output Power on CC1101 (swra168.pdf)
[8]
CC1190 Data Sheet (swrs08.pdf)
[9]
DN032 Options for Cost Optimizes CC11xx Matching (swra346.pdf)
[10]
CC110LEM / CC115LEM 433 MHz Reference Design (swrr081.zip)
[11]
CC110LEM / CC115LEM 868 - 915 MHz Reference Design (swrr082.zip)
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CC115L
27 General Information
27.1 Document History
Revision
Date
Description/Changes
SWRA105
05.24.2011
Initial Release
SWRS105A
08.09.2011
Added two registers (CHANNR and MDMCFG0) in addition to the MDMCFG1.CHANSPC_E
register field. Changes made to Section 17. Hyperlinks added to the CC110LEM /
CC115LEM 433 MHz Reference Design and the CC110LEM / CC115LEM 868 - 915
MHz Reference Design
Table 32: Document History
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PACKAGE OPTION ADDENDUM
www.ti.com
8-Sep-2011
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package
Drawing
Pins
Package Qty
Eco Plan
(2)
Lead/
Ball Finish
MSL Peak Temp
(3)
CC115LRTKR
ACTIVE
VQFN
RTK
20
3000
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
CC115LRTKT
ACTIVE
VQFN
RTK
20
250
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
Samples
(Requires Login)
(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.
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 1
PACKAGE MATERIALS INFORMATION
www.ti.com
7-Sep-2011
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
CC115LRTKR
VQFN
RTK
20
3000
330.0
12.4
4.3
4.3
1.5
8.0
12.0
Q2
CC115LRTKT
VQFN
RTK
20
250
330.0
12.4
4.3
4.3
1.5
8.0
12.0
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
7-Sep-2011
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
CC115LRTKR
VQFN
RTK
20
3000
340.5
333.0
20.6
CC115LRTKT
VQFN
RTK
20
250
340.5
333.0
20.6
Pack Materials-Page 2
CC115L
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TI 保证其所销售的硬件产品的性能符合TI 标准保修的适用规范。仅在TI 保证的范围内 , 且TI 认为有必要时才会使用测试或其它质
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http://www.ti.com.cn/microcontroll
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RFID 系统
http://www.ti.com.cn/rfidsys
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www.ti.com.cn/radiofre
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