CC3100 [TI]
CC3100 SimpleLink Wi-Fi Network Processor, Internet-of-Things Solution for MCU Applications;型号: | CC3100 |
厂家: | TEXAS INSTRUMENTS |
描述: | CC3100 SimpleLink Wi-Fi Network Processor, Internet-of-Things Solution for MCU Applications |
文件: | 总44页 (文件大小:1999K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
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CC3100
SWAS031D –JUNE 2013–REVISED FEBRUARY 2015
CC3100 SimpleLink™ Wi-Fi® Network Processor,
Internet-of-Things Solution for MCU Applications
1 Device Overview
1.1 Features
1
– RX Sensitivity
• CC3100 SimpleLink Wi-Fi Consists of Wi-Fi
Network Processor and Power-Management
Subsystems
•
•
–95.7 dBm @ 1 DSSS
–74.0 dBm @ 54 OFDM
• Wi-Fi CERTIFIED™ Chip
– Application Throughput
• Wi-Fi Network Processor Subsystem
– Featuring Wi-Fi Internet-On-a-Chip™
– Dedicated ARM MCU
•
•
UDP: 16 Mbps
TCP: 13 Mbps
• Host Interface
Completely Offloads Wi-Fi and Internet
Protocols from the External Microcontroller
– Interfaces with 8-, 16-, and 32-Bit MCU or
ASICs Over SPI or UART Interface
– Wi-Fi Driver and Multiple Internet Protocols in
ROM
– 802.11 b/g/n Radio, Baseband, and Medium
Access Control (MAC), Wi-Fi Driver, and
Supplicant
– Low External Host Driver Footprint: Less Than
7KB of Code Memory and 700 B of RAM
Memory Required for TCP Client Application
• Power-Management Subsystem
– Integrated DC-DC Supports a Wide Range of
Supply Voltage:
– TCP/IP Stack
•
Industry-Standard BSD Socket Application
Programming Interfaces (APIs)
8 Simultaneous TCP or UDP Sockets
2 Simultaneous TLS and SSL Sockets
•
•
VBAT Wide-Voltage Mode: 2.1 to 3.6 V
Preregulated 1.85-V Mode
•
•
– Advanced Low-Power Modes
•
•
•
Hibernate with RTC: 4 µA
Low-Power Deep Sleep (LPDS): 115 µA
RX Traffic (MCU Active): 53 mA @
54 OFDM
TX Traffic (MCU Active): 223 mA @
54 OFDM, Maximum Power
– Powerful Crypto Engine for Fast, Secure Wi-Fi
and Internet Connections with 256-Bit AES
Encryption for TLS and SSL Connections
– Station, AP, and Wi-Fi Direct® Modes
– WPA2 Personal and Enterprise Security
– SimpleLink Connection Manager for
Autonomous and Fast Wi-Fi Connections
– SmartConfig™ Technology, AP Mode, and
WPS2 for Easy and Flexible Wi-Fi Provisioning
•
•
Idle Connected: 690 µA @ DTIM = 1
• Clock Source
– 40.0-MHz Crystal with Internal Oscillator
– 32.768-kHz Crystal or External RTC Clock
• Package and Operating Temperature
– 0.5-mm Pitch, 64-Pin, 9-mm × 9-mm QFN
– Ambient Temperature Range: –40°C to 85°C
– TX Power
•
•
18.0 dBm @ 1 DSSS
14.5 dBm @ 54 OFDM
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
CC3100
SWAS031D –JUNE 2013–REVISED FEBRUARY 2015
www.ti.com
1.2 Applications
•
For Internet-of-Things applications, such as:
–
–
–
–
–
–
Cloud Connectivity
Home Automation
Home Appliances
Access Control
–
–
–
–
–
Internet Gateway
Industrial Control
Smart Plug and Metering
Wireless Audio
Security Systems
Smart Energy
IP Network Sensor Nodes
1.3 Description
Connect any low-cost, low-power microcontroller (MCU) to the Internet of Things (IoT). The CC3100
device is the industry's first Wi-Fi CERTIFIED chip used in the wireless networking solution. The CC3100
device is part of the new SimpleLink Wi-Fi family that dramatically simplifies the implementation of Internet
connectivity. The CC3100 device integrates all protocols for Wi-Fi and Internet, which greatly minimizes
host MCU software requirements. With built-in security protocols, the CC3100 solution provides a robust
and simple security experience. Additionally, the CC3100 device is a complete platform solution including
various tools and software, sample applications, user and programming guides, reference designs and the
TI E2E™ support community. The CC3100 device is available in an easy-to-layout QFN package.
The Wi-Fi network processor subsystem features a Wi-Fi Internet-on-a-Chip and contains an additional
dedicated ARM MCU that completely offloads the host MCU. This subsystem includes an 802.11 b/g/n
radio, baseband, and MAC with a powerful crypto engine for fast, secure Internet connections with 256-bit
encryption. The CC3100 device supports Station, Access Point, and Wi-Fi Direct modes. The device also
supports WPA2 personal and enterprise security and WPS 2.0. This subsystem includes embedded
TCP/IP and TLS/SSL stacks, HTTP server, and multiple Internet protocols.
The power-management subsystem includes integrated DC-DC converters supporting a wide range of
supply voltages. This subsystem enables low-power consumption modes, such as the hibernate with RTC
mode requiringabout 4 μA of current.
The CC3100 device can connect to any 8, 16, or 32-bit MCU over the SPI or UART Interface. The device
driver minimizes the host memory footprint requirements requiring less than 7KB of code memory and 700
B of RAM memory for a TCP client application.
Device Information(1)
PART NUMBER
CC3100R11MRGCR/T
PACKAGE
BODY SIZE
QFN (64)
9.0 mm x 9.0 mm
(1) For all available packages, see the orderable addendum at the end of the datasheet.
2
Device Overview
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SWAS031D –JUNE 2013–REVISED FEBRUARY 2015
1.4 Functional Block Diagram
Figure 1-1 shows the CC3100 hardware overview.
RAM
ROM
WiFi Driver
TCP/IP & TLS/SSL
Stacks
ARM Processor
Crypto Engine
MAC Processor
Baseband
SPI
UART
DC2DC
PA
BAT Monitor
Oscillators
Radio
LNA
SWAS031-A
Figure 1-1. CC3100 Hardware Overview
Figure 1-2 shows an overview of the CC3100 embedded software.
User Application
SimpleLink Driver
SPI or UART Driver
External Microcontroller
Internet Protocols
TLS/SSL
Embedded Internet
Embedded Wi-Fi
TCP/IP
Supplicant
Wi-Fi Driver
Wi-Fi MAC
Wi-Fi Baseband
Wi-Fi Radio
ARM Processor (Wi-Fi Network Processor)
SWAS031-B
Figure 1-2. CC3100 Software Overview
Copyright © 2013–2015, Texas Instruments Incorporated
Device Overview
3
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SWAS031D –JUNE 2013–REVISED FEBRUARY 2015
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Table of Contents
1
Device Overview ......................................... 1
1.1 Features .............................................. 1
1.2 Applications........................................... 2
1.3 Description............................................ 2
1.4 Functional Block Diagram ............................ 3
Revision History ......................................... 4
Terminal Configuration and Functions.............. 5
3.1 Pin Attributes ......................................... 5
Specifications ............................................ 8
4.1 Absolute Maximum Ratings .......................... 8
4.2 Handling Ratings ..................................... 8
4.3 Power-On Hours...................................... 8
4.4 Recommended Operating Conditions ................ 8
4.5 Brown-Out and Black-Out ............................ 9
4.12 External Interfaces .................................. 22
4.13 Host UART .......................................... 23
Detailed Description ................................... 26
5.1 Overview ............................................ 26
5.2 Functional Block Diagram........................... 27
5.3 Wi-Fi Network Processor Subsystem ............... 27
5.4 Power-Management Subsystem .................... 28
5.5 Low-Power Operating Modes ....................... 29
5.6 Memory.............................................. 29
Applications and Implementation................... 31
6.1 Application Information .............................. 31
Device and Documentation Support ............... 35
7.1 Device Support ...................................... 35
7.2 Documentation Support ............................. 36
7.3 Community Resources.............................. 36
7.4 Trademarks.......................................... 36
7.5 Electrostatic Discharge Caution..................... 36
7.6 Glossary ............................................. 36
5
2
3
4
6
7
4.6
Electrical Characteristics (3.3 V, 25°C) ............. 10
4.7 WLAN Receiver Characteristics .................... 10
4.8 WLAN Transmitter Characteristics.................. 10
4.9 Current Consumption ............................... 11
4.10 Thermal Characteristics for RGC Package ......... 13
4.11 Timing and Switching Characteristics............... 13
8
Mechanical Packaging and Orderable
Information .............................................. 37
2 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision C (August 2014) to Revision D
Page
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Added Wi-Fi CERTIFIED ............................................................................................................ 1
Changed TCP value from 12 Mbps in Section 1.1, Features .................................................................. 1
Changed part number in Device Information table from CC3100 .............................................................. 2
Changed pin 19 from NC and pin 18 from reserved in Figure 3-1 ............................................................. 5
Changed pin 19 from NC in Table 3-1 ............................................................................................. 6
Added to pin 2 (nHIB) description in Table 3-1 ................................................................................... 6
Changed pins 8 and 14 to active low .............................................................................................. 6
Changed pin 15 to active high ..................................................................................................... 6
Added note in Section 4.4, Recommended Operating Conditions, on avoiding the PA auto-protect feature ............ 8
Added Section 4.5, Brown-Out and Black-Out ................................................................................... 9
Added Table 4-1 ..................................................................................................................... 9
Added VIL (nRESET pin) and corresponding note in Section 4.6, Electrical Characteristics (3.3 V, 25°C) ............ 10
Added note on RX current measurement in Section 4.9 Current Consumption. ........................................... 11
Changed Thib_min description from "minimum pulse width of nHIB = 0" in Table 4-4 ...................................... 16
Added footnote in Table 4-4 to ensure that the nHIB pulse width is kept above the minimum requirement. .......... 16
Changed frequency accuracy from ±20 ppm in Table 4-5 .................................................................... 18
Added 4.11.3.6, WLAN Filter Requirements .................................................................................... 19
Added note on asserting nCS (active low signal) in Table 4-10 .............................................................. 20
Changed HOST_SPI_CS to HOST_SPI_nCS in Table 4-13.................................................................. 23
Changed H_IRQ to HOST_INTR(IRQ) in Figure 4-17 ......................................................................... 24
Changed TCP of item 17 from 12 Mbps in Table 5-1 .......................................................................... 28
Changed part number of item 13 from XCC3100RTD in Table 6-1 ......................................................... 32
Added note following Table 6-1 ................................................................................................... 32
Changed part number of item 13 from XCC3100RTD in Table 6-2 .......................................................... 34
Added note following Table 6-2 ................................................................................................... 34
4
Revision History
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3 Terminal Configuration and Functions
Figure 3-1 shows pin assignments for the 64-pin QFN package.
48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33
VDD_RAM
UART1_nRTS
RTC_XTAL_P
RTC_XTAL_N
NC
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
nRESET
RF_BG
RESERVED
RESERVED
NC
VIN_IO2
UART1_TX
VDD_DIG2
UART1_RX
TEST_58
TEST_59
TEST_60
UART1_nCTS
TEST_62
NC
NC
NC
CC3100
LDO_IN2
VDD_PLL
WLAN_XTAL_P
WLAN_XTAL_N
SOP2/TCXO_EN
NC
RESERVED
NC
NC
NC
1
2
3
4
5
6
7
8
9
10 11 12 13 14 15 16
Figure 3-1. QFN 64-Pin Assignments (Top View)
3.1 Pin Attributes
Table 3-1 describes the CC3100 pins.
NOTE
If an external device drives a positive voltage to signal pads when the CC3100 device is not
powered, DC current is drawn from the other device. If the drive strength of the external
device is adequate, an unintentional wakeup and boot of the CC3100 device can occur. To
prevent current draw, TI recommends one of the following:
•
•
•
All devices interfaced to the CC3100 device must be powered from the same power rail
as the CC3100 device.
Use level-shifters between the CC3100 device and any external devices fed from other
independent rails.
The nRESET pin of the CC3100 device must be held low until the VBAT supply to the
device is driven and stable.
Copyright © 2013–2015, Texas Instruments Incorporated
Terminal Configuration and Functions
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Table 3-1. Pin Attributes
PIN
DEFAULT FUNCTION
STATE AT RESET
AND HIBERNATE
I/O TYPE
DESCRIPTION
1
2
NC
Hi-Z
Hi-Z
N/A
I
Unused; leave unconnected.
nHIB
Hibernate signal input to the NWP (active low).
This is connected to the MCU GPIO. If the
GPIO from the MCU can float while the MCU
enters low power, consider adding a pull-up
resistor on the board to avoid floating.
3
4
Reserved
Hi-Z
Hi-Z
NA
I
Reserved for future use
FORCE_AP
For forced AP mode, pull to high on the board
using 100k resistor. Otherwise, pull down to
ground using 100k resistor.(1)
5
6
HOST_SPI_CLK
HOST_SPI_MOSI
HOST_SPI_MISO
HOST_SPI_nCS
VDD_DIG1
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
I
Host interface SPI clock
I
Host interface SPI data input
Host interface SPI data output
Host interface SPI chip select (active low)
Digital core supply (1.2 V)
7
O
8
I
9
Power
10
11
12
13
VIN_IO1
Power
I/O supply
FLASH_SPI_CLK
FLASH_SPI_MOSI
O
O
I
Serial flash interface: SPI clock
Serial flash interface: SPI data out
Serial flash interface: SPI data in
FLASH _SPI_MISO
(active high)
14
FLASH _SPI_nCS
Hi-Z
O
Serial flash interface: SPI chip select (active
low)
15
16
17
18
19
20
21
HOST_INTR
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
O
Interrupt output (active high)
Unused; leave unconnected.
Unused; leave unconnected.
Unused; leave unconnected.
Connect 100K pull-down to ground.
Unused; leave unconnected.
NC
N/A
N/A
N/A
N/A
N/A
O
NC
NC
Reserved
NC
SOP2/TCXO_EN
Enable signal for external TCXO. Add 10k
pulldown to ground.
22
23
24
25
26
27
28
29
30
31
32
WLAN_XTAL_N
WLAN_XTAL_P
VDD_PLL
LDO_IN2
NC
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Analog
Analog
Power
Power
N/A
N/A
N/A
O
Connect the WLAN 40-MHz XTAL here.
Connect the WLAN 40-MHz XTAL here.
Internal PLL power supply (1.4 V nominal)
Input to internal LDO
Unused; leave unconnected.
Unused; leave unconnected.
Unused; leave unconnected.
Reserved for future use
NC
NC
Reserved
Reserved
RF_BG
O
Reserved for future use
RF
2.4-GHz RF TX/RX
nRESET
I
RESET input for the device. Active low input.
Use RC circuit (100k || 0.1 µF) for power on
reset.
33
34
35
36
37
VDD_PA_IN
SOP1
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Power
N/A
Power supply for the RF power amplifier (PA)
Add 100K pulldown to ground.
Add 100K pulldown to ground.
Input to internal LDO
SOP0
N/A
LDO_IN1
Power
Power
VIN_DCDC_ANA
Power supply for the DC-DC converter for
analog section
(1) Using a configuration file stored on flash, the vendor can optionally block any possibility of bringing up AP using the FORCE_AP pin.
Terminal Configuration and Functions
6
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Table 3-1. Pin Attributes (continued)
PIN
DEFAULT FUNCTION
STATE AT RESET
AND HIBERNATE
I/O TYPE
DESCRIPTION
38
39
40
41
42
DCDC_ANA_SW
VIN_DCDC_PA
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Power
Power
Power
Power
Power
Analog DC-DC converter switch output
PA DC-DC converter input supply
DCDC_PA_SW_P
DCDC_PA_SW_N
DCDC_PA_OUT
PA DC-DC converter switch output +ve
PA DC-DC converter switch output –ve
PA DC-DC converter output. Connect the
output capacitor for DC-DC here.
43
44
DCDC_DIG_SW
VIN_DCDC_DIG
Hi-Z
Hi-Z
Power
Power
Digital DC-DC converter switch output
Power supply input for the digital DC-DC
converter
45
46
47
48
49
50
51
DCDC_ANA2_SW_P
DCDC_ANA2_SW_N
VDD_ANA2
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Power
Power
Power
Power
Power
O
Analog2 DC-DC converter switch output +ve
Analog2 DC-DC converter switch output –ve
Analog2 power supply input
VDD_ANA1
Analog1 power supply input
VDD_RAM
Power supply for the internal RAM
UART host interface
UART1_nRTS
RTC_XTAL_P
Analog
32.768 kHz XTAL_P/external CMOS level
clock input
52
RTC_XTAL_N
Hi-Z
Analog
32.768 kHz XTAL_N/100k external pullup for
external clock
53
54
55
NC
Hi-Z
Hi-Z
Hi-Z
N/A
Power
O
Unused. Leave unconnected.
VIN_IO2
UART1_TX
I/O power supply. Same as battery voltage.
UART host interface. Connect to test point on
prototype for flash programming.
56
57
VDD_DIG2
UART1_RX
Hi-Z
Hi-Z
Power
I
Digital power supply (1.2 V)
UART host interface. Connect to test point on
prototype for flash programming.
58
59
60
61
62
63
64
65
TEST_58
TEST_59
TEST_60
UART1_nCTS
TEST_62
NC
N/A
N/A
O
Test signal. Connect to an external test point.
Test signal. Connect to an external test point.
Test signal. Connect to an external test point.
UART host interface
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
I
O
Test signal. Connect to an external test point.
Leave unconnected
I/O
I/O
Power
NC
Leave unconnected
GND
Ground tab used as thermal and electrical
ground
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Terminal Configuration and Functions
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4 Specifications
All measurements are referenced at the device pins, unless otherwise indicated. All specifications are over
process and voltage, unless otherwise indicated.
4.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)
PARAMETERS
PINS
37, 39, 44
10, 54
MIN
MAX
3.8
UNIT
V
VBAT and VIO
–0.5
VIO-VBAT (differential)
Digital inputs
0.0
V
–0.5
–0.5
–0.5
–40
VIO + 0.5
2.1
V
RF pins
V
Analog pins (XTAL)
2.1
V
Operating temperature range (TA
)
+85
°C
4.2 Handling Ratings
MIN
MAX
UNIT
Tstg
Storage temperature range
Electrostatic discharge
–55
+125
°C
Human body model (HBM), per ANSI/ESDA/JEDEC
JS-001, all pins(1)
–2000
–500
+2000
+500
V
VESD
Charged device model (CDM), per JEDEC
specification JESD22-C101, all pins(2)
V
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
4.3 Power-On Hours
CONDITIONS
POH
17,500(1)
TAmbient up to 85°C, assuming 20% active mode and 80% sleep mode
(1) The CC3100 device can be operated reliably for 10 years.
4.4 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
(1)(2)
PARAMETERS
PINS
CONDITIONS(3) (4)
MIN
TYP
MAX
UNIT
VBAT, VIO (shorted to VBAT
VBAT, VIO (shorted to VBAT
Ambient thermal slew
)
10, 37, 39,
44, 54
Direct battery connection
2.1
3.3
3.6
V
)
10, 37, 39,
44, 54
Preregulated 1.85 V
1.76
–20
1.85
1.9
20
V
°C/minute
(1) Operating temperature is limited by crystal frequency variation.
(2) When operating at an ambient temperature of over 75°C, the transmit duty cycle must remain below 50% to avoid the auto-protect
feature of the power amplifier. If the auto-protect feature triggers, the device takes a maximum of 60 seconds to restart the transmission.
(3) To ensure WLAN performance, ripple on the 2.1- to 3.3-V supply must be less than ±300 mV.
(4) To ensure WLAN performance, ripple on the 1.85-V supply must be less than 2% (±40 mV).
8
Specifications
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4.5 Brown-Out and Black-Out
The device enters a brown-out condition whenever the input voltage dips below VBROWN (see Figure 4-1 and
Figure 4-2). This condition must be considered during design of the power supply routing, especially if operating
from a battery. High-current operations (such as a TX packet) cause a dip in the supply voltage, potentially
triggering a brown-out. The resistance includes the internal resistance of the battery, contact resistance of the
battery holder (4 contacts for a 2 x AA battery) and the wiring and PCB routing resistance.
Figure 4-1. Brown-Out and Black-Out Levels (1 of 2)
Figure 4-2. Brown-Out and Black-Out Levels (2 of 2)
In the brown-out condition, all sections of the device shut down except for the Hibernate module (including the
32-kHz RTC clock), which remains on. The current in this state can reach approximately 400 µA.
The black-out condition is equivalent to a hardware reset event in which all states within the device are lost.
Table 4-1 lists the brown-out and black-out voltage levels.
Table 4-1. Brown-Out and Black-out Voltage Levels
CONDITION
VOLTAGE LEVEL
UNIT
V
Vbrownout
Vblackout
2.1
1.67
V
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UNIT
4.6 Electrical Characteristics (3.3 V, 25°C)
PARAMETER
TEST
MIN
NOM
MAX
CONDITIONS
CIN
VIH
VIL
IIH
Pin capacitance
4
pF
V
High-level input voltage
Low-level input voltage
High-level input current
Low-level input current
0.65 × VDD
–0.5
VDD + 0.5 V
0.35 × VDD
V
5
5
nA
nA
V
IIL
VOH
High-level output voltage
(VDD = 3.0 V)
2.4
VOL
Low-level output voltage
(VDD = 3.0 V)
0.4
V
IOH
IOL
High-level source current, VOH = 2.4
Low-level sink current, VOH = 0.4
6
6
mA
mA
Pin Internal Pullup and Pulldown (25°C)
TEST
CONDITIONS
MIN
5
NOM
MAX
UNIT
µA
PARAMETER
IOH
IOL
VIL
Pull-Up current, VOH = 2.4
(VDD = 3.0 V)
10
Pull-Down current, VOL = 0.4
(VDD = 3.0 V)
nRESET(1)
5
µA
0.6
V
(1) The nRESET pin must be held below 0.6 V for the device to register a reset.
4.7 WLAN Receiver Characteristics
TA = +25°C, VBAT = 2.1 to 3.6 V. Parameters measured at SoC pin on channel 7 (2442 MHz)
Parameter
Condition (Mbps)
1 DSSS
Min
Typ
Max
Units
–95.7
–93.6
–88.0
–90.0
–89.0
–86.0
–80.5
–74.0
–89.0
–71.0
–4.0
2 DSSS
11 CCK
6 OFDM
Sensitivity
9 OFDM
(8% PER for 11b rates, 10% PER for
11g/11n rates)(10% PER)(1)
18 OFDM
36 OFDM
54 OFDM
MCS0 (GF)(2)
MCS7 (GF)(2)
802.11b
dBm
Maximum input level
(10% PER)
802.11g
–10.0
(1) Sensitivity is 1-dB worse on channel 13 (2472 MHz).
(2) Sensitivity for mixed mode is 1-dB worse.
4.8 WLAN Transmitter Characteristics
10
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TA = +25°C, VBAT = 2.1 to 3.6 V. Parameters measured at SoC pin on channel 7 (2442 MHz).(1)
Parameter
Condition(2)
Min
Typ
18.0
18.0
18.3
17.3
17.3
17.0
16.0
14.5
13.0
Max
Units
dBm
ppm
1 DSSS
2 DSSS
11 CCK
6 OFDM
Maximum RMS output power measured at
1 dB from IEEE spectral mask or EVM
9 OFDM
18 OFDM
36 OFDM
54 OFDM
MCS7 (MM)
Transmit center frequency accuracy
–25
25
(1) Channel-to-channel variation is up to 2 dB. The edge channels (2412 and 2472 MHz) have reduced TX power to meet FCC emission
limits.
(2) In preregulated 1.85-V mode, maximum TX power is 0.25 to 0.75 dB lower for modulations higher than 18 OFDM.
4.9 Current Consumption
TA = +25°C, VBAT = 3.6 V
PARAMETER
TEST CONDITIONS(1) (2)
TX power level = 0
TX power level = 4
TX power level = 0
TX power level = 4
TX power level = 0
TX power level = 4
MIN TYP(3) MAX UNIT
272
188
248
179
1 DSSS
6 OFDM
54 OFDM
TX
223
mA
160
1 DSSS
53
53
RX(4)
54 OFDM
Idle connected(5)
LPDS
0.690
0.115
Hibernate(6)
4
µA
VBAT = 3.3 V
VBAT = 2.1 V
VBAT = 1.85 V
450
670
700
(7)(4)
Peak calibration current
mA
(1) TX power level = 0 implies maximum power (see Figure 4-3 through Figure 4-5). TX power level = 4 implies output power backed off
approximately 4 dB.
(2) The CC3100 system is a constant power-source system. The active current numbers scale based on the VBAT voltage supplied.
(3) External serial-flash-current consumption is not included.
(4) The RX current is measured with a 1-Mbps throughput rate.
(5) DTIM = 1
(6) For the 1.85-V mode, the Hibernate current is higher by 50 µA across all operating modes because of leakage into the PA and analog
power inputs.
(7) The complete calibration can take up to 17 mJ of energy from the battery over a time of 24 ms . Calibration is performed sparingly,
typically when coming out of Hibernate and only if temperature has changed by more than 20°C or the time elapsed from prior
calibration is greater than 24 hours.
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1 DSSS
19.00
17.00
280.00
264.40
249.00
233.30
218.00
202.00
186.70
171.00
Color by
TX Power (dBm)
15.00
13.00
IBAT (VBAT @ 3.6 V)
11.00
9.00
7.00
5.00
3.00
1.00
155.60
140.00
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
TX power level setting
Note: The area enclosed in the circle represents a significant reduction in current when transitioning from TX power
level 3 to 4. In the case of lower range requirements (14 dbm output power), TI recommends using TX power level 4
to reduce the current.
Figure 4-3. TX Power and IBAT vs TX Power Level Settings (1 DSSS)
6 OFDM
19.00
17.00
280.00
264.40
249.00
233.30
218.00
202.00
186.70
171.00
Color by
TX Power (dBm)
15.00
13.00
IBAT (VBAT @ 3.6 V)
11.00
9.00
7.00
5.00
3.00
1.00
155.60
140.00
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
TX power level setting
Figure 4-4. TX Power and IBAT vs TX Power Level Settings (6 OFDM)
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54 OFDM
19.00
17.00
280.00
Color by
264.40
249.00
233.30
218.00
202.00
186.70
171.00
TX Power (dBm)
15.00
13.00
IBAT (VBAT @ 3.6 V)
11.00
9.00
7.00
5.00
3.00
1.00
155.60
140.00
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
TX power level setting
Figure 4-5. TX Power and IBAT vs TX Power Level Settings (54 OFDM)
4.10 Thermal Characteristics for RGC Package
AIR FLOW
PARAMETER
0 lfm (C/W)
150 lfm (C/W)
250 lfm (C/W)
500 lfm (C/W)
θja
Ψjt
Ψjb
θjc
23
0.2
2.3
6.3
2.4
14.6
0.2
12.4
0.3
10.8
0.1
2.3
2.2
2.4
θjb
4.11 Timing and Switching Characteristics
4.11.1 Power Supply Sequencing
For proper operation of the CC3100 device, perform the recommended power-up sequencing as follows:
1. Tie VBAT (pins 37, 39, 44) and VIO (pins 54 and 10) together on the board.
2. Hold the RESET pin low while the supplies are ramping up. TI recommends using a simple RC circuit (100K ||
0.1 µF, RC = 10 ms).
3. For an external RTC clock, ensure that the clock is stable before RESET is deasserted (high).
For timing diagrams, see Section 4.11.2, Reset Timing.
4.11.2 Reset Timing
4.11.2.1 nRESET (32K XTAL)
Figure 4-6 shows the reset timing diagram for the 32K XTAL first-time power-up and reset removal.
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Figure 4-6. First-Time Power-Up and Reset Removal Timing Diagram (32K XTAL)
Table 4-2 describes the timing requirements for the 32K XTAL first-time power-up and reset removal.
Table 4-2. First-Time Power-Up and Reset Removal Timing Requirements (32K XTAL)
Item
Name
Description
Min
Typ
Max
Depends on
application board
power supply, decap,
and so on
T1
Supply settling time
3 ms
Hardware wakeup
time
T2
T3
25 ms
1.35 s
32-kHz XTAL settling
+ firmware
initialization time +
radio calibration
Initialization time
14
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4.11.2.2 nRESET (External 32K)
Figure 4-7 shows the reset timing diagram for the external 32K first-time power-up and reset removal.
Figure 4-7. First-Time Power-Up and Reset Removal Timing Diagram (External 32K)
Table 4-3 describes the timing requirements for the external 32K first-time power-up and reset removal.
Table 4-3. First-Time Power-Up and Reset Removal Timing Requirements (External 32K)
Item
Name
Description
Min
Typ
Max
Depends on
application board
power supply, decap,
and so on
T1
Supply settling time
3 ms
Hardware wakeup
time
T2
T3
25 ms
Firmware initialization
time + radio
Initialization time
250 ms
calibration
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4.11.2.3 Wakeup from Hibernate
Figure 4-8 shows the timing diagram for wakeup from the hibernate state.
Figure 4-8. nHIB Timing Diagram
NOTE
The 32.768-kHz XTAL is kept enabled by default when the chip goes to hibernate in response to
nHIB being pulled low.
Table 4-4 describes the timing requirements for nHIB.
Table 4-4. nHIB Timing Requirements
Item
Name
Description
Min
Typ
Max
Thib_min
Minimum hibernate
time
Minimum pulse width 10 ms
of nHIB being low(1)
(2)
Twake_from_hib
Hardware wakeup
time plus firmware
initialization time
See
.
50 ms
(1) Ensure that the nHIB pulse width is kept above the minimum requirement under all conditions (such as power up, MCU reset, and so
on).
(2) If temperature changes by more than 20°C, initialization time from HIB can increase by 200 ms due to radio calibration.
4.11.3 Clock Specifications
The CC3100 device requires two separate clocks for its operation:
•
•
A slow clock running at 32.768 kHz is used for the RTC.
A fast clock running at 40 MHz is used by the device for the internal processor and the WLAN subsystem.
The device features internal oscillators that enable the use of cheaper crystals rather than dedicated TCXOs for
these clocks. The RTC can also be fed externally to provide reuse of an existing clock on the system and reduce
overall cost.
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4.11.3.1 Slow Clock Using Internal Oscillator
The RTC crystal connected on the device supplies the free-running slow clock. The accuracy of the slow clock
frequency must be 32.768 kHz ±150 ppm. In this mode of operation, the crystal is tied between RTC_XTAL_P
(pin 51) and RTC_XTAL_N (pin 52) with a suitable load capacitance.
Figure 4-9 shows the crystal connections for the slow clock.
51
RTC_XTAL_P
10 pF
GND
32.768 kHz
52
RTC_XTAL_N
10 pF
GND
SWAS031-028
Figure 4-9. RTC Crystal Connections
4.11.3.2 Slow Clock Using an External Clock
When an RTC clock oscillator is present in the system, the CC3100 device can accept this clock directly as an
input. The clock is fed on the RTC_XTAL_P line and the RTC_XTAL_N line is held to VIO. The clock must be a
CMOS-level clock compatible with VIO fed to the device.
Figure 4-10 shows the external RTC clock input connection.
32.768 kHz
RTC_XTAL_P
Host system
VIO
100 K
RTC_XTAL_N
SWAS031-029
Figure 4-10. External RTC Clock Input
4.11.3.3 Fast Clock (Fref) Using an External Crystal
The CC3100 device also incorporates an internal crystal oscillator to support a crystal-based fast clock. The
XTAL is fed directly between WLAN_XTAL_P (pin 23) and WLAN_XTAL_N (pin 22) with suitable loading
capacitors.
Figure 4-11 shows the crystal connections for the fast clock.
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23
WLAN_XTAL_P
6.2 pF
GND
40 MHz
22
WLAN_XTAL_N
6.2 pF
GND
SWAS031-030
Figure 4-11. Fast Clock Crystal Connections
4.11.3.4 Fast Clock (Fref) Using an External Oscillator
The CC3100 device can accept an external TCXO/XO for the 40-MHz clock. In this mode of operation, the clock
is connected to WLAN_XTAL_P (pin 23). WLAN_XTAL_N (pin 22) is connected to GND. The external TCXO/XO
can be enabled by TCXO_EN (pin 21) from the device to optimize the power consumption of the system.
If the TCXO does not have an enable input, an external LDO with an enable function can be used. Using the
LDO improves noise on the TCXO power supply.
Figure 4-12 shows the connection.
Vcc
XO (40MHz)
EN
CC3200
TCXO_EN
82 pF
WLAN_XTAL_P
OUT
WLAN_XTAL_N
SWAS031-087
Figure 4-12. External TCXO Input
Table 4-5 lists the external Fref clock requirements.
Table 4-5. External Fref Clock Requirements (–40°C to +85°C)
Characteristics
Condition
Sym
Min
Typ
Max
Unit
MHz
ppm
%
Frequency
40.00
Frequency accuracy (Initial + temp + aging)
Frequency input duty cycle
±25
55
45
50
Clock voltage limits
Sine or clipped
sine wave, AC
coupled
Vpp
0.7
1.2
Vpp
Phase noise @ 40 MHz
@ 1 kHz
–125
–138.5
–143
dBc/Hz
dBc/Hz
dBc/Hz
KΩ
@ 10 kHz
@ 100 kHz
Input impedance
Resistance
12
Capacitance
7
pF
18
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4.11.3.5 Input Clocks/Oscillators
Table 4-6 lists the RTC crystal requirements.
Table 4-6. RTC Crystal Requirements
CHARACTERISTICS
Frequency
CONDITION
SYM
MIN
TYP
MAX
UNIT
kHz
ppm
kΩ
32.768
Frequency accuracy
Crystal ESR
Initial + temp + aging
±150
70
32.768 kHz, C1 = C2 = 10 pF
Table 4-7 lists the external RTC digital clock requirements.
Table 4-7. External RTC Digital Clock Requirements
CHARACTERISTICS
Frequency
CONDITION
SYM
MIN
TYP
MAX
UNIT
Hz
32768
Frequency accuracy
±150
ppm
(Initial + temp + aging)
Input transition time tr/tf (10% to 90%)
Frequency input duty cycle
Slow clock input voltage limits
tr/tf
100
80
ns
%
20
50
Square wave, DC coupled
Vih
Vil
0.65 × VIO
VIO
V
0
1
0.35 × VIO
V peak
MΩ
pF
Input impedance
5
Table 4-8 lists the WLAN fast-clock crystal requirements.
Table 4-8. WLAN Fast-Clock Crystal Requirements
CHARACTERISTICS
Frequency
CONDITION
SYM
MIN
TYP
MAX
UNIT
MHz
ppm
Ohm
40
Frequency accuracy
Crystal ESR
Initial + temp + aging
±25
60
40 MHz, C1 = C2 = 6.2 pF
40
50
4.11.3.6 WLAN Filter Requirements
The device requires an external bandpass filter to meet the various emission standards, including FCC. Table 4-
9 presents the attenuation requirements for the bandpass filter. TI recommends using the same filter used in the
reference design to ease the process of certification.
Table 4-9. WLAN Filter Requirements
Requirements
Parameter
Frequency (MHz)
Min
Typ
Max
Units
dB
Return loss
Insertion loss(1)
2412 to 2484
2412 to 2484
10
1
1.5
dB
(1) Insertion loss directly impacts output power and sensitivity. At customer discretion, insertion loss can be relaxed to meet attenuation
requirements.
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Table 4-9. WLAN Filter Requirements (continued)
Requirements
Typ Max
Parameter
Frequency (MHz)
Min
30
20
30
45
20
20
20
35
20
Units
800 to 830
1600 to 1670
3200 to 3300
4000 to 4150
4800 to 5000
5600 to 5800
6400 to 6600
7200 to 7500
7500 to 10000
2412 to 2484
Bandpass
45
25
48
50
25
25
35
45
25
50
Attenuation
dB
Reference Impendence
Filter type
Ω
4.11.4 Interfaces
This section describes the interfaces that are supported by the CC3100 device:
•
•
•
Host SPI
Flash SPI
Host UART
4.11.4.1 Host SPI Interface Timing
I2
CLK
I6
I7
MISO
MOSI
I9
I8
SWAS032-017
Figure 4-13. Host SPI Interface Timing
Table 4-10. Host SPI Interface Timing Parameters
Parameter
Number
Parameter(1)
Parameter Name
Min
Max
Unit
I1
F
Clock frequency @ VBAT = 3.3 V
Clock frequency @ VBAT ≤ 2.1 V
Clock period
20
12
MHz
(2)
I2
I3
I4
I5
I6
I7
I8
tclk
50
ns
ns
ns
%
tLP
tHT
D
Clock low period
25
25
55
Clock high period
Duty cycle
45
4
tIS
RX data setup time
RX data hold time
ns
ns
tIH
tOD
4
TX data output delay
20
(1) The timing parameter has a maximum load of 20 pf at 3.3 V.
(2) Ensure that nCS (active-low signa)l is asserted 10 ns before the clock is toggled. nCS can be deasserted 10 ns after the clock edge.
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Table 4-10. Host SPI Interface Timing Parameters (continued)
Parameter
Parameter(1)
Parameter Name
Min
Max
Unit
Number
I9
tOH
TX data hold time
24
ns
4.11.4.2 Flash SPI Interface Timing
I2
CLK
I6
I7
MISO
MOSI
I9
I8
SWAS032-017
Figure 4-14. Flash SPI Interface Timing
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Table 4-11. Flash SPI Interface Timing Parameters
Parameter
Number
Parameter
Parameter Name
Min
Max
Unit
I1
I2
I3
I4
I5
I6
I7
I8
I9
F
Clock frequency
Clock period
20
MHz
ns
ns
ns
%
tclk
tLP
tHT
D
50
Clock low period
Clock high period
Duty cycle
25
25
55
45
1
tIS
RX data setup time
RX data hold time
TX data output delay
TX data hold time
ns
ns
ns
ns
tIH
2
tOD
tOH
8.5
8
4.12 External Interfaces
4.12.1 SPI Flash Interface
The external serial flash stores the user profiles and firmware patch updates. The CC3100 device acts as
a master in this case; the SPI serial flash acts as the slave device. This interface can work up to a speed
of 20 MHz.
Figure 4-15 shows the SPI flash interface.
CC3100 (master)
Serial flash
FLASH_SPI_CLK
SPI_CLK
SPI_CS
FLASH_SPI_nCS
FLASH_SPI_MISO
FLASH_SPI_MOSI
SPI_MISO
SPI_MOSI
SWAS031-026
Figure 4-15. SPI Flash Interface
Table 4-12 lists the SPI flash interface pins.
Table 4-12. SPI Flash Interface
Pin Name
Description
FLASH_SPI_CLK
FLASH_SPI_CS
FLASH_SPI_MISO
FLASH_SPI_MOSI
Clock (up to 20 MHz) CC3100 device to serial flash
CS (active low) signal from CC3100 device to serial flash
Data from serial flash to CC3100 device
Data from CC3100 device to serial flash
4.12.2 SPI Host Interface
The device interfaces to an external host using the SPI interface. The CC3100 device can interrupt the
host using the HOST_INTR line to initiate the data transfer over the interface. The SPI host interface can
work up to a speed of 20 MHz.
Figure 4-16 shows the SPI host interface.
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CC3100 (slave)
MCU
HOST_SPI_CLK
SPI_CLK
SPI_nCS
HOST_SPI_nCS
HOST_SPI_MISO
HOST_SPI_MOSI
HOST_INTR
SPI_MISO
SPI_MOSI
INTR
nHIB
GPIO
SWAS031-027
Figure 4-16. SPI Host Interface
Table 4-13 lists the SPI host interface pins.
Table 4-13. SPI Host Interface
Pin Name
Description
HOST_SPI_CLK
HOST_SPI_nCS
Clock (up to 20 MHz) from MCU host to CC3100 device
CS (active low) signal from MCU host to CC3100 device
Data from MCU host to CC3100 device
HOST_SPI_MOSI
HOST_INTR
HOST_SPI_MISO
nHIB
Interrupt from CC3100 device to MCU host
Data from CC3100 device to MCU host
Active-low signal that commands the CC3100 device to enter hibernate mode (lowest power
state)
4.13 Host UART
The SimpleLink device requires the UART configuration described in Table 4-14.
Table 4-14. SimpleLink UART Configuration
Property
Baud rate
Supported CC3100 Configuration
115200 bps, no auto-baud rate detection, can be changed by the host up to 3 Mbps using a special command
Data bits
8 bits
Flow control
Parity
CTS/RTS
None
Stop bits
1
Bit order
LSBit first
Active high
Rising edge or level 1
Little-endian only(1)
Host interrupt polarity
Host interrupt mode
Endianness
(1) The SimpleLink device does not support automatic detection of the host length while using the UART interface.
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4.13.1 5-Wire UART Topology
Figure 4-17 shows the typical 5-wire UART topology comprised of 4 standard UART lines plus one IRQ
line from the device to the host controller to allow efficient low power mode.
RTS
CTS
TX
RTS
CTS
TX
HOST MCU
UART
CC3100 SL
UART
RX
RX
HOST_INTR(IRQ)
HOST_INTR(IRQ)
SWAS031-088
Figure 4-17. Typical 5-Wire UART Topology
This is the typical and recommended UART topology because it offers the maximum communication
reliability and flexibility between the host and the SimpleLink device.
4.13.2 4-Wire UART Topology
The 4-wire UART topology eliminates the host IRQ line (see Figure 4-18). Using this topology requires
one of the following conditions to be met:
•
•
Host is always awake or active.
Host goes to sleep but the UART module has receiver start-edge detection for auto wakeup and does
not lose data.
RTS
CTS
TX
RTS
CTS
TX
HOST MCU
UART
CC3100 SL
UART
RX
RX
H_IRQ
H_IRQ
X
SWAS031-089
Figure 4-18. 4-Wire UART Configuration
4.13.3 3-Wire UART Topology
The 3-wire UART topology requires only the following lines (see Figure 4-19):
•
•
•
RX
TX
CTS
RTS
CTS
TX
RTS
CTS
TX
X
HOST MCU
UART
CC3100 SL
UART
RX
RX
H_IRQ
H_IRQ
X
SWAS031-090
Figure 4-19. 3-Wire UART Topology
Using this topology requires one of the following conditions to be met:
Host always stays awake or active.
•
24
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•
•
Host goes to sleep but the UART module has receiver start-edge detection for auto wakeup and does
not lose data.
Host can always receive any amount of data transmitted by the SimpleLink device because there is no
flow control in this direction.
Because there is no full flow control, the host cannot stop the SimpleLink device to send its data; thus, the
following parameters must be carefully considered:
•
•
•
Max baud rate
RX character interrupt latency and low-level driver jitter buffer
Time consumed by the user's application
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5 Detailed Description
5.1 Overview
5.1.1 Device Features
5.1.1.1 WLAN
•
•
•
•
•
802.11b/g/n integrated radio, modem, and MAC supporting WLAN communication as a BSS station
with CCK and OFDM rates in the 2.4-GHz ISM band
Auto-calibrated radio with a single-ended 50-Ω interface enables easy connection to the antenna
without requiring expertise in radio circuit design.
Advanced connection manager with multiple user-configurable profiles stored in an NVMEM allows
automatic fast connection to an access point without user or host intervention.
Supports all common Wi-Fi security modes for personal and enterprise networks with on-chip security
accelerators
SmartConfig technology: A 1-step, 1-time process to connect a CC3100-enabled device to the home
wireless network, removing dependency on the I/O capabilities of the host MCU; thus, it is usable by
deeply embedded applications.
•
802.11 transceiver mode: Allows transmitting and receiving of proprietary data through a socket
without adding MAC or PHY headers. This mode provides the option to select the working channel,
rate, and transmitted power. The receiver mode works together with the filtering options.
5.1.1.2 Network Stack
•
Integrated IPv4 TCP/IP stack with BSD socket APIs for simple Internet connectivity with any MCU,
microprocessor, or ASIC
•
•
Support of eight simultaneous TCP, UDP, or RAW sockets
Built-in network protocols: ARP, ICMP, DHCP client, and DNS client for easy connection to the local
network and the Internet
•
Service discovery: Multicast DNS service discovery lets a client advertise its service without a
centralized server. After connecting to the access point, the CC3100 device provides critical
information, such as device name, IP, vendor, and port number.
5.1.1.3 Host Interface and Driver
•
•
•
Interfaces over a 4-wire serial peripheral interface (SPI) with any MCU or a processor at a clock speed
of 20 MHz.
Interfaces over UART with any MCU with a baud rate up to 3 Mbps. A low footprint driver is provided
for TI MCUs and is easily ported to any processor or ASIC.
Simple APIs enable easy integration with any single-threaded or multithreaded application.
5.1.1.4 System
•
•
Works from a single preregulated power supply or connects directly to a battery
Ultra-low leakage when disabled (hibernate mode) with a current of less than 4 µA with the RTC
running
•
Integrated clock sources
26
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5.2 Functional Block Diagram
Figure 5-1 shows the functional block diagram of the CC3100 SimpleLink Wi-Fi solution.
VCC
SPI
FLASH
40-MHz
XTAL
32-kHz
XTAL
32 kHz
CC3100
Network processor
MCU
nHIB
HOST_INTR
SPI/UART
SWAS031-018
Figure 5-1. Functional Block Diagram
5.3 Wi-Fi Network Processor Subsystem
The Wi-Fi network processor subsystem includes a dedicated ARM MCU to completely offload the host
MCU along with an 802.11 b/g/n radio, baseband, and MAC with a powerful crypto engine for a fast,
secure WLAN and Internet connections with 256-bit encryption. The CC3100 device supports station, AP,
and Wi-Fi Direct modes. The device also supports WPA2 personal and enterprise security and WPS 2.0.
The Wi-Fi network processor includes an embedded IPv4 TCP/IP stack.
Table 5-1 summarizes the NWP features.
Table 5-1. Summary of Features Supported by the NWP Subsystem
Item
1
Domain
TCP/IP
TCP/IP
TCP/IP
TCP/IP
TCP/IP
TCP/IP
TCP/IP
TCP/IP
TCP/IP
TCP/IP
TCP/IP
Category
Network Stack
Network Stack
Protocols
Feature
IPv4
Details
Baseline IPv4 stack
Base protocols
2
TCP/UDP
DHCP
3
Client and server mode
Support ARP protocol
4
Protocols
ARP
5
Protocols
DNS/mDNS
IGMP
DNS Address resolution and local server
6
Protocols
Up to IGMPv3 for multicast management
7
Applications
Applications
Applications
Security
mDNS
Support multicast DNS for service publishing over IP
Service discovery protocol over IP in local network
8
mDNS-SD
9
Web Sever/HTTP Server URL static and dynamic response with template.
10
11
TLS/SSL
TLS/SSL
TLS v1.2 (client/server)/SSL v3.0
Security
For the supported Cipher Suite, go to SimpleLink Wi-Fi
CC3100 SDK.
12
13
14
TCP/IP
WLAN
WLAN
Sockets
Connection
MAC
RAW Sockets
Policies
User-defined encapsulation at WLAN MAC/PHY or IP
layers
Allows management of connection and reconnection
policy
Promiscuous mode
Filter-based Promiscuous mode frame receiver
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Table 5-1. Summary of Features Supported by the NWP Subsystem (continued)
Item
Domain
Category
Feature
Details
15
WLAN
Performance
Initialization time
From enable to first connection to open AP less than
50 ms
16
17
18
19
WLAN
WLAN
WLAN
WLAN
Performance
Performance
Provisioning
Provisioning
Throughput
Throughput
WPS2
UDP = 16 Mbps
TCP = 13 Mbps
Enrollee using push button or PIN method.
AP Config
AP mode for initial product configuration (with
configurable Web page and beacon Info element)
20
21
22
WLAN
WLAN
WLAN
Provisioning
Role
SmartConfig
Station
Alternate method for initial product configuration
802.11bgn Station with legacy 802.11 power save
Role
Soft AP
802.11 bg single station with legacy 802.11 power
save
23
24
25
26
27
28
29
30
31
32
33
34
WLAN
WLAN
WLAN
WLAN
WLAN
WLAN
WLAN
WLAN
WLAN
WLAN
WLAN
WLAN
Role
P2P
P2P operation as GO
P2P operation as CLIENT
WPA2 personal security
WPA2 enterprise security
EAP-TLS
Role
P2P
Security
Security
Security
Security
Security
Security
Security
Security
Security
Security
STA-Personal
STA-Enterprise
STA-Enterprise
STA-Enterprise
STA-Enterprise
STA-Enterprise
STA-Enterprise
STA-Enterprise
STA-Enterprise
AP-Personal
EAP-PEAPv0/TLS
EAP-PEAPv1/TLS
EAP-PEAPv0/MSCHAPv2
EAP-PEAPv1/MSCHAPv2
EAP-TTLS/EAP-TLS
EAP-TTLS/MSCHAPv2
WPA2 personal security
5.4 Power-Management Subsystem
The CC3100 power-management subsystem contains DC-DC converters to accommodate the differing
voltage or current requirements of the system.
•
Digital DC-DC
Input: VBAT wide voltage (2.1 to 3.6 V) or preregulated 1.85 V
ANA1 DC-DC
–
•
–
–
Input: VBAT wide voltage (2.1 to 3.6 V)
In preregulated 1.85-V mode, the ANA1 DC-DC converter is bypassed.
•
PA DC-DC
–
–
Input: VBAT wide voltage (2.1 to 3.6 V)
In preregulated 1.85-V mode, the PA DC-DC converter is bypassed.
In preregulated 1.85-V mode, the ANA1 DC-DC and PA DC-DC converters are bypassed. The CC3100
device is a single-chip WLAN radio solution used on an embedded system with a wide-voltage supply
range. The internal power management, including DC-DC converters and LDOs, generates all of the
voltages required for the device to operate from a wide variety of input sources. For maximum flexibility,
the device can operate in the modes described in the following sections.
5.4.1 VBAT Wide-Voltage Connection
In the wide-voltage battery connection, the device is powered directly by the battery. All other voltages
required to operate the device are generated internally by the DC-DC converters. This scheme is the most
common mode for the device as it supports wide-voltage operation from 2.1 to 3.6 V (for electrical
connections, see Section 6.1.1, Typical Application – CC3100 Wide-Voltage Mode).
28
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5.4.2 Preregulated 1.85 V
The preregulated 1.85-V mode of operation applies an external regulated 1.85 V directly at the pins 10,
25, 33, 36, 37, 39, 44, 48, and 54 of the device. The VBAT and the VIO are also connected to the 1.85-V
supply. This mode provides the lowest BOM count version in which inductors used for PA DC-DC and
ANA1 DC-DC (2.2 and 1 µH) and a capacitor (22 µF) can be avoided. For electrical connections, see
Section 6.1.2, Typical Application – CC3100 Preregulated 1.85-V Mode.
In the preregulated 1.85-V mode, the regulator providing the 1.85 V must have the following
characteristics:
•
•
Load current capacity ≥900 mA.
Line and load regulation with <2% ripple with 500 mA step current and settling time of <4 µs with the
load step.
•
The regulator must be placed very close to the CC3100 device so that the IR drop to the device is very
low.
5.5 Low-Power Operating Modes
This section describes the low-power modes supported by the device to optimize battery life.
5.5.1 Low-Power Deep Sleep
The low-power deep-sleep (LPDS) mode is an energy-efficient and transparent sleep mode that is entered
automatically during periods of inactivity based on internal power optimization algorithms. The device can
wake up in less than 3 ms from the internal timer or from any incoming host command. Typical battery
drain in this mode is 115 µA. During LPDS mode, the device retains the software state and certain
configuration information. The operation is transparent to the external host; thus, no additional handshake
is required to enter or exit this sleep mode.
5.5.2 Hibernate
The hibernate mode is the lowest power mode in which all of the digital logic is power-gated. Only a small
section of the logic powered directly by the main input supply is retained. The real-time clock (RTC) is kept
running and the device wakes up once the nHIB line is asserted by the host driver. The wake-up time is
longer than LPDS mode at about 50 ms.
NOTE
Wake-up time can be extended to 75 ms if a patch is loaded from the serial flash.
5.6 Memory
5.6.1 External Memory Requirements
The CC3100 device maintains a proprietary file system on the SFLASH. The CC3100 file system stores
the service pack file, system files, configuration files, certificate files, web page files, and user files. By
using a format command through the API, users can provide the total size allocated for the file system.
The starting address of the file system cannot be set and is always located at the beginning of the
SFLASH. The applications microcontroller must access the SFLASH memory area allocated to the file
system directly through the CC3100 file system. The applications microcontroller must not access the
SFLASH memory area directly.
The file system manages the allocation of SFLASH blocks for stored files according to download order,
which means that the location of a specific file is not fixed in all systems. Files are stored on SFLASH
using human-readable file names rather than file IDs. The file system API works using plain text, and file
encryption and decryption is invisible to the user. Encrypted files can be accessed only through the file
system.
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All file types can have a maximum of 128 supported files in the file system. All files are stored in blocks of
4KB and thus use a minimum of 4KB of flash space. Encrypted files with fail-safe support and optional
security are twice the original size and use a minimum of 8KB. Encrypted files are counted as fail safe in
terms of space. The maximum file size is 16MB.
Table 5-2 lists the SFLASH size recommendations.
Table 5-2. CC3100 SFLASH Size Recommendations
Item
Typical Fail-Safe
20KB
Typical NonFail-Safe
File system
20KB
112KB
108KB
2Mb
Service pack
224KB
System and configuration files
Total
216KB
4Mb
Recommended
8Mb
4Mb
The CC3100 device supports JEDEC specification SFDP (serial flash device parameters). The following
SFLASH devices are verified for functionality with the CC3100 device in addition to the ones in the
reference design:
•
•
•
•
•
Micron (N25Q128-A13BSE40): 128Mb
Spansion (S25FL208K): 8Mb
Winbond (W25Q16V): 16Mb
Adesto (AT25DF081A): 8Mb
Macronix (MX25L12835F-M2): 128Mb
For compatibility with the CC3100 device, the SFLASH device must support the following commands:
•
•
Command 0x9F (read the device ID [JEDEC]). Procedure: SEND 0x9F, READ 3 bytes.
Command 0x05 (read the status of the SFLASH). Procedure: SEND 0x05, READ 1 byte. Assume bit 0
is busy and bit 1 is write enable.
•
•
•
•
•
Command 0x06 (set write enable). Procedure: SEND 0x06, read status until write-enable bit is set.
Command 0xC7 (chip erase). Procedure: SEND 0xC7, read status until busy bit is cleared.
Command 0x03 (read data). Procedure: SEND 0x03, SEND 24-bit address, read n bytes.
Command 0x02 (write page). Procedure: SEND 0x02, SEND 24-bit address, write n bytes (0<n<256).
Command 0x20 (sector erase). Procedure: SEND 0x20, SEND 24-bit address, read status until busy
bit is cleared. Sector size is assumed to be always 4K.
30
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6 Applications and Implementation
6.1 Application Information
6.1.1 Typical Application – CC3100 Wide-Voltage Mode
Figure 6-1 shows the schematics for an application using the CC3100 wide-voltage mode.
Consider adding extra decoupling capacitors
if the battery cannot source the peak current.
VBAT
VBAT
VBAT
R1
100k
C27
100uF
C26
100uF
C6
C2
C3
C4
C5
0.1uF
4.7uF
4.7uF
4.7uF
0.1uF
C1
0.1uF
FL1
2.4GHz Filter
DEA202450BT-1294C1-H
U1
L2
3.6nH
E1
2.45GHz Ant
AH316M245001-T
1
3
IN
OUT
C8
1.0pF
VBAT
Antenna match
(Depends on type of
antenna)
50 Ohm
31
RF_BG
L1
2.2uH
R75
38
100k
DCDC_ANA_SW
U2
VBAT
C7
VBAT
48
14
13
12
11
1
2
5
6
8
7
3
4
VDD_ANA1
FLASH_SPI_CSn
FLASH_SPI_MISO
FLASH_SPI_MOSI
FLASH_SPI_CLK
CS
VCC
10uF
DOUT
DIN
RESET
WP
C9
0.1uF
C10
0.1uF
R79
CLK
GND
36
25
100k
LDO_IN1
LDO_IN2
R76
100k
100k
nRESET
R77
8M (1M x 8)
M25PX80-VMN6TP
61
50
55
57
Flash programming
CC_UART1_CTS
CC_UART1_RTS
CC_UART1_TX
UART1_nCTS
UART1_nRTS
UART1_TX
C11
0.1uF
C12
0.1uF
(Connect TP to UART, nRESET
to be driven by external programmer)
RTS/CTS optional
L3
CC_UART1_RX
UART1_RX
40
41
42
DCDC_PA_SW_P
DCDC_PA_SW_N
DCDC_PA_OUT
58
59
TP1
1uH
TEST_58
TEST_59
R78
TP2
100k
Needed only when using
UART as host interface
33
60
62
C13
22uF
C14
22uF
TP3
TP4
VDD_PA_IN
TEST_60
TEST_62
C15
1.0uF
63
64
3
NC
NC
L4
2.2uH
43
9
R84
100k
R83
100k
DCDC_DIG_SW
VDD_DIG1
RESERVED
FORCE_AP
4
C16
10uF
56
C17
0.1uF
VDD_DIG2
C18
2
CC_nHIB
nHIB
HOST_SPI_nCS
HOST_SPI_CLK
HOST_SPI_MOSI
HOST_SPI_MISO
HOSTINTR
0.1uF
HOST INTERFACE
(Do not leave nHIB floating.
Always connect to host)
8
CC_SPI_CS
CC_SPI_CLK
CC_SPI_DIN
CC_SPI_DOUT
CC_IRQ
45
46
47
DCDC_ANA2_SW_P
DCDC_ANA2_SW_N
VDD_ANA2
5
6
7
15
49
24
R81
R82
10k
100k
VDD_RAM
VDD_PLL
C21
0.1uF
18
C20
0.1uF
RESERVED
27
28
26
NC_27
NC_28
NC_26
23
22
WLAN_XTALP
WLAN_XTALM
C22
52
51
RTC_XTAL_N
RTC_XTAL_P
Y2
10pF
C23
53
29
30
1
NC_53
NC_29
NC_30
NC_01
Y1
Crystal
32.768KHz
ABS07-32.768KHZ-T
C25
C24
6.2pF
10pF
6.2pF
CC3100R
40 MHz
Q24FA20H00396
40MHz, ESR < 50, CL = 8pF, 20ppm
R9
100k
R4
100k
R10
100k
R11
10k
Figure 6-1. Schematics for CC3100 Wide-Voltage Mode Application
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Table 6-1 lists the bill of materials for an application using the CC3100 wide-voltage mode.
Table 6-1. Bill of Materials for CC3100 Wide Voltage Mode ApplicationTable 6-1
Item
Qty
Reference
Value
Manufacturer
Part Number
Description
1
12
C1 C5 C6 C9
C10 C11 C12
C17 C18 C20
C21 C28
0.1 µF
Taiyo Yuden
LMK105BJ104KV-F
CAP CER 0.1 µF 10 V 10% X5R 0402
2
3
3
1
C2 C3 C4
4.7 µF
Samsung Electro- CL05A475MQ5NRNC
Mechanics
America, Inc
CAP CER 4.7 µF 6.3 V 20% X5R 0402
C8
1.0 pF Murata Electronics GJM1555C1H1R0BB01D CAP CER 1 pF 50 V NP0 0402
North America
4
5
1
1
C13
C16
22 µF
10 µF
Taiyo Yuden
AMK107BBJ226MAHT
CAP CER 22 µF 4 V 20% X5R 0603
Murata Electronics GRM188R60J106ME47D CAP CER 10 µF 6.3 V 20% X5R 0603
North America
6
2
C22 C23
10 pF
Murata Electronics GRM1555C1H100FA01D CAP CER 10 pF 50 V 1% NP0 0402
North America
7
8
9
2
2
1
C24 C25
C26 C27
E1
6.2 pF
Kemet
CBR04C609B1GAC
CAP CER 6 pF 100 V NP0 0402
100 µF
TDK Corportation C3216X5R0J107M160AB CAP CER 100 µF 6.3 V 20% X5R 1206
2.45G
Hz Ant
Taiyo Yuden
TDK-Epcos
AH316M245001-T
ANT BLUETOOTH WLAN ZIGBEE
WIMAX
10
11
12
1
1
1
FL1
L2
2.4G Hz
Filter
DEA202450BT-1294C1-H FILTER BANDPASS 2.45 GHZ WLAN
SMD
3.6 nH Murata Electronics LQP15MN3N6B02D
North America
INDUCTOR 3.6 nH 0.1 nH 0402
L4
2.2 µH Murata Electronics LQM2HPN2R2MG0L
North America
INDUCTOR 2.2 µH 20% 1300 mA 1008
13
14
1
1
U1
U2
CC3100 Texas Instruments CC3100R1
802.11bg Wi-Fi Processor
8M (1M
x 8)
Winbond
W25Q80BWZPIG
ABS07-32.768KHZ-T
Q24FA20H00396
IC FLASH 8 Mb 75 MHZ 8WSON
15
16
1
1
Y1
Y2
Crystal
Abracon
CRYSTAL 32.768 KHZ 12.5 pF SMD
CRYSTAL 40 MHZ 8 pF SMD
Corporation
Crystal
Epson
NOTE
Use any 5% tolerance resistor 0402 or higher package.
6.1.2 Typical Application – CC3100 Preregulated 1.85-V Mode
Figure 6-2 shows the schematics for an application using the CC3100 preregulated 1.85-V mode.
32
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5
4
3
2
1
Consider adding extra decoupling capacitors
if the battery cannot source the peak currents.
1.85V
1.85V
1.85V
R1
100k
C27
100uF
C26
100uF
C6
C2
C3
C4
C5
0.1uF
4.7uF
4.7uF
4.7uF
0.1uF
C1
D
D
C
B
A
0.1uF
FL1
2.4GHz Filter
DEA202450BT-1294C1-H
U3
L2
3.6nH
E1
2.45GHz Ant
AH316M245001-T
1
3
IN
OUT
C8
1.0pF
1.85V
1.85V
Antenna match
(Depends on type of
antenna)
50 Ohm
31
RF_BG
R75
38
100k
DCDC_ANA_SW
U2
1.85V
48
14
13
12
11
1
2
5
6
8
7
3
4
1.85V
VDD_ANA1
FLASH_SPI_CSn
FLASH_SPI_MISO
FLASH_SPI_MOSI
FLASH_SPI_CLK
CS
VCC
DOUT
DIN
RESET
WP
C9
0.1uF
C10
0.1uF
R79
CLK
GND
36
25
100k
LDO_IN1
LDO_IN2
R76
R77
100k
100k
nRESET
8M (1M x 8)
W25Q80BWZPIG
C7
61
50
55
57
Flash programming
CC_UART1_CTS
CC_UART1_RTS
CC_UART1_TX
UART1_nCTS
UART1_nRTS
UART1_TX
C11
0.1uF
C12
0.1uF
(Connect TP to UART, nRESET
to be driven by external programmer)
RTS/CTS optional
4.7uF
CC_UART1_RX
UART1_RX
40
41
42
C
B
A
DCDC_PA_SW_P
DCDC_PA_SW_N
DCDC_PA_OUT
58
59
TP1
TP2
TEST_58
TEST_59
Needed only when using
UART as host interface
R78
100k
33
60
62
TP3
TP4
VDD_PA_IN
TEST_60
TEST_62
C13
22uF
63
64
3
NC
NC
L4
2.2uH
43
9
R83
R84
100k
100k
DCDC_DIG_SW
VDD_DIG1
RESERVED
FORCE_AP
4
C16
C17
0.1uF
56
VDD_DIG2
10uF
C18
2
CC_nHIB
nHIB
HOST_SPI_nCS
HOST_SPI_CLK
HOST_SPI_MOSI
HOST_SPI_MISO
HOSTINTR
0.1uF
HOST INTERFACE
(Do not leave nHIB floating.
Always connect to host)
8
CC_SPI_CS
45
46
47
DCDC_ANA2_SW_P
DCDC_ANA2_SW_N
VDD_ANA2
5
CC_SPI_CLK
CC_SPI_DIN
CC_SPI_DOUT
CC_IRQ
6
7
15
49
24
R81
R82
10k
100k
VDD_RAM
VDD_PLL
C21
0.1uF
18
C20
0.1uF
RESERVED
27
28
26
NC_27
NC_28
NC_26
23
22
WLAN_XTALP
WLAN_XTALM
C22
52
51
RTC_XTAL_N
RTC_XTAL_P
Y2
10pF
C23
53
29
30
1
NC_53
NC_29
NC_30
NC_01
Y1
Crystal
32.768KHz
ABS07-32.768KHZ-T
C25
C24
6.2pF
10pF
6.2pF
CC3100
40 MHz
Q24FA20H00396
40MHz, ESR < 50, CL = 8pF, 20ppm
R9
100k
R4
100k
R10
100k
R11
10k
5
4
3
2
1
Figure 6-2. Schematics for CC3100 Preregulated 1.85-V Mode Application
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Table 6-1 lists the bill of materials for an application using the CC3100 preregulated 1.85-V mode.
Table 6-2. Bill of Materials for CC3100 Preregulated 1.85-V Mode Application
Item
Qty
Reference
Value
Manufacturer
Part Number
Description
1
12
C1 C5 C6 C9
C10 C11 C12
C17 C18 C20
C21 C28
0.1 µF
Taiyo Yuden
LMK105BJ104KV-F
Capacitor, Ceramic: 0.1 µF 10 V 10%
X5R 0402
2
4
C2 C3 C4 C7
4.7 µF
Samsung Electro- CL05A475MQ5NRNC
Capacitor, Ceramic: 4.7 µF 6.3 V 20%
X5R 0402
Mechanics
America, Inc
3
4
5
6
7
8
9
1
1
1
2
2
2
1
C8
C13
1.0 pF Murata Electronics GJM1555C1H1R0BB01D Capacitor, Ceramic: 1 pF 50 V NP0 0402
North America
22 µF
10 µF
10 pF
6.2 pF
100 µF
Taiyo Yuden
AMK107BBJ226MAHT
Capacitor, Ceramic: 22 µF 4 V 20% X5R
0603
C16
Murata Electronics GRM188R60J106ME47D Capacitor, Ceramic: 10 µF 6.3 V 20%
North America X5R 0603
C22 C23
C24 C25
C26 C27
E1
Murata Electronics GRM1555C1H100FA01D Capacitor, Ceramic: 10 pF 50 V 1% NP0
North America
0402
Kemet
CBR04C609B1GAC
Capacitor, Ceramic: 6 pF 100 V NP0
0402
TDK Corportation C3216X5R0J107M160AB Capacitor, Ceramic: 100 µF 6.3 V 20%
X5R 1206
2.45-
GHz
Ant
Taiyo Yuden
AH316M245001-T
Antenna, Bluetooth: WLAN ZigBee
WIMAX
10
1
FL1
2.4-
GHz
Filter
TDK-Epcos
DEA202450BT-1294C1-H Filter, Bandpass: 2.45 GHz WLAN SMD
11
12
1
1
L2
L4
3.6 nH Murata Electronics LQP15MN3N6B02D
North America
Inductor: 3.6 nH 0.1 nH 0402
2.2 µH Murata Electronics LQM2HPN2R2MG0L
North America
Inductor: 2.2 µH 20% 1300 mA 1008
13
14
1
1
U1
U2
CC3100 Texas Instruments CC3100R1
802.11bg Wi-Fi Processor
8M
(1M x
8)
Winbond
W25Q80BWZPIG
IC Flash 8 Mb 75 MHz 8WSON
15
16
1
1
Y1
Y2
Crystal
Abracon
Corporation
ABS07-32.768KHZ-T
Q24FA20H00396
Crystal 32.768 kHz 12.5 pF SMD
Crystal 40 MHZ 8 pF SMD
Crystal
Epson
NOTE
Use any 5% tolerance resistor 0402 or higher package.
34
Applications and Implementation
Copyright © 2013–2015, Texas Instruments Incorporated
Submit Documentation Feedback
Product Folder Links: CC3100
CC3100
www.ti.com
SWAS031D –JUNE 2013–REVISED FEBRUARY 2015
7 Device and Documentation Support
7.1 Device Support
7.1.1 Development Support
The CC3100 evaluation board includes a set of tools and documentation to help the user during the
development phase.
7.1.1.1 Radio Tool
The SimpleLink radio tool is a utility for operating and testing the CC3100 chipset RF performance
characteristics during development of the application board. The CC3100 device has an auto-calibrated
radio that enables easy connection to the antenna without requiring expertise in radio circuit design.
7.1.1.2 Uniflash Flash Programmer
The Uniflash flash programmer utility allows end users to communicate with the SimpleLink device to
update the serial flash. The easy GUI interface enables flashing of files (including read-back verification
option), storage format (secured and nonsecured formatting), version reading for boot loader and chip ID,
and so on.
7.1.2 Device Nomenclature
To designate the stages in the product development cycle, TI assigns prefixes to the part numbers of the
CC3100 device and support tools (see Figure 7-1).
X
CC
3
1
0
0
R
1
1M
RGC
R
PREFIX
X = perproduction device
no prefix = production device
PACKAGING
R = tape/reel
T = small reel
DEVICE FAMILY
CC = wireless connectivity
PACKAGE
RGC = 9x9 QFN
SERIES NUMBER
3 = Wi-Fi Centric
Figure 7-1. CC3100 Device Nomenclature
Copyright © 2013–2015, Texas Instruments Incorporated
Device and Documentation Support
35
Submit Documentation Feedback
Product Folder Links: CC3100
CC3100
SWAS031D –JUNE 2013–REVISED FEBRUARY 2015
www.ti.com
7.2 Documentation Support
The following documents provide support for the CC3100 device.
SWRU370
SWRU375
SWRU368
SWRU371
SWRC288
CC3100 and CC3200 SimpleLink Wi-Fi and IoT Solution Layout Guidelines
CC3100 SimpleLink Wi-Fi and IoT Solution Getting Started Guide
CC3100 SimpleLink Wi-Fi and IoT Solution Programmer's Guide
CC3100 SimpleLink Wi-Fi and IoT Solution BoosterPack Hardware User Guide
CC3100 SimpleLink Wi-Fi and IoT Solution Booster Pack Design Files
7.3 Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the
respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views;
see TI's Terms of Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster
collaboration among engineers. At e2e.ti.com, you can ask questions, share knowledge,
explore ideas and help solve problems with fellow engineers.
TI Embedded Processors Wiki Texas Instruments Embedded Processors Wiki. Established to help
developers get started with Embedded Processors from Texas Instruments and to foster
innovation and growth of general knowledge about the hardware and software surrounding
these devices.
7.4 Trademarks
SimpleLink, Internet-On-a-Chip, SmartConfig, E2E are trademarks of Texas Instruments.
Wi-Fi CERTIFIED is a trademark of Wi-Fi Alliance.
Wi-Fi, Wi-Fi Direct are registered trademarks of Wi-Fi Alliance.
All other trademarks are the property of their respective owners.
7.5 Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
7.6 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
36
Device and Documentation Support
Copyright © 2013–2015, Texas Instruments Incorporated
Submit Documentation Feedback
Product Folder Links: CC3100
CC3100
www.ti.com
SWAS031D –JUNE 2013–REVISED FEBRUARY 2015
8 Mechanical Packaging and Orderable Information
The following pages include mechanical packaging and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and
revision of this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
Copyright © 2013–2015, Texas Instruments Incorporated
Mechanical Packaging and Orderable Information
Submit Documentation Feedback
Product Folder Links: CC3100
37
PACKAGE OPTION ADDENDUM
www.ti.com
23-Jul-2015
PACKAGING INFORMATION
Orderable Device
CC3100R11MRGC
CC3100R11MRGCR
Status Package Type Package Pins Package
Eco Plan
Lead/Ball Finish
MSL Peak Temp
Op Temp (°C)
-40 to 85
Device Marking
Samples
Drawing
Qty
(1)
(2)
(6)
(3)
(4/5)
ACTIVE
VQFN
VQFN
RGC
64
64
260
Green (RoHS
& no Sb/Br)
CU
Level-3-260C-168 HR
CC3100R1
CC3100R1
ACTIVE
RGC
2500
Green (RoHS
& no Sb/Br)
CU
Level-3-260C-168 HR
-40 to 85
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6) Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
Addendum-Page 1
PACKAGE OPTION ADDENDUM
www.ti.com
23-Jul-2015
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
11-Apr-2015
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
B0
K0
P1
W
Pin1
Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant
(mm) W1 (mm)
CC3100R11MRGCR
VQFN
RGC
64
2500
330.0
16.4
9.3
9.3
1.1
12.0
16.0
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
11-Apr-2015
*All dimensions are nominal
Device
Package Type Package Drawing Pins
VQFN RGC 64
SPQ
Length (mm) Width (mm) Height (mm)
367.0 367.0 38.0
CC3100R11MRGCR
2500
Pack Materials-Page 2
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