EFM8 Laser Bee Family
EFM8LB1 Data Sheet
The EFM8LB1, part of the Laser Bee family of MCUs, is a performance line of 8-bit microcontrollers with a comprehensive analog and digital feature set in small packages.
KEY FEATURES
• Pipelined 8-bit 8051 MCU Core with
72 MHz operating frequency
These devices offer state-of-the-art performance by integrating 14-bit ADC, internal
calibrated temperature sensor (±3 °C), and up to four 12-bit DACs into small packages,
making them ideal for the most stringent analog requirement applications. With an efficient, pipelined 8051 core with maximum operating frequency at 72 MHz, various communication interfaces, and four channels of configurable logic, the EFM8LB1 family is
optimal for many embedded applications.
• Up to 29 multifunction I/O pins
• One 14-bit, 900 ksps ADC
• Up to four 12-bit DACs with
synchronization and PWM capabilities
• Two low-current analog comparators with
built-in reference DACs
• Internal calibrated temperature sensor
(±3 °C)
EFM8LB1 applications include the following:
• Optical network modules
• Precision instrumentation
• Internal 72 MHz and 24.5 MHz oscillators
accurate to ±2%
• Industrial control and automation
• Smart sensors
• Four channels of Configurable Logic
• 6-channel PWM / PCA
• Six 16-bit general-purpose timers
Core / Memory
Clock Management
CIP-51 8051 Core
(72 MHz)
Flash Program
Memory
RAM Memory
(up to 4352 bytes)
(up to 64 KB)
Debug Interface
with C2
Energy Management
External
Oscillator
High Frequency
72 MHz RC
Oscillator
Low Frequency
RC Oscillator
High Frequency
24.5 MHz RC
Oscillator
Internal LDO
Regulator
Power-On Reset
Brown-Out Detector
8-bit SFR bus
Serial Interfaces
2 x UART
I2C / SMBus
SPI
High-Speed
I2C Slave
I/O Ports
External
Interrupts
General
Purpose I/O
Pin Reset
Pin Wakeup
Timers and Triggers
Timers
0/1/2/5
PCA/PWM
Watchdog
Timer
Timer 3/4
4 x Configurable Logic Units
Analog Interfaces
ADC
2x
Comparators
Up to 4 x
Voltage DAC
Internal
Voltage
Reference
Security
16-bit CRC
Lowest power mode with peripheral operational:
Normal
Idle
Suspend
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�EFM8LB1 Data Sheet
Feature List
1. Feature List
The EFM8LB1 device family are fully integrated, mixed-signal system-on-a-chip MCUs. Highlighted features are listed below.
• Core:
• Analog:
• Pipelined CIP-51 Core
• 14/12/10-Bit Analog-to-Digital Converter (ADC)
• Fully compatible with standard 8051 instruction set
• Internal calibrated temperature sensor (±3 °C)
• 70% of instructions execute in 1-2 clock cycles
• 4 x 12-Bit Digital-to-Analog Converters (DAC)
• 72 MHz maximum operating frequency
• 2 x Low-current analog comparators with adjustable refer• Memory:
ence
• Up to 64 kB flash memory (63 kB user-accessible), in-sys• Communications and Digital Peripherals:
tem re-programmable from firmware in 512-byte sectors
• 2 x UART, up to 3 Mbaud
• Up to 4352 bytes RAM (including 256 bytes standard 8051
• SPI™ Master / Slave, up to 12 Mbps
RAM and 4096 bytes on-chip XRAM)
• SMBus™/I2C™ Master / Slave, up to 400 kbps
• Power:
• I2C High-Speed Slave, up to 3.4 Mbps
• Internal LDO regulator for CPU core voltage
• 16-bit CRC unit, supporting automatic CRC of flash at 256• Power-on reset circuit and brownout detectors
byte boundaries
• I/O: Up to 29 total multifunction I/O pins:
• 4 Configurable Logic Units
• Up to 25 pins 5 V tolerant under bias
• Timers/Counters and PWM:
• Selectable state retention through reset events
• 6-channel Programmable Counter Array (PCA) supporting
• Flexible peripheral crossbar for peripheral routing
PWM, capture/compare, and frequency output modes
• 5 mA source, 12.5 mA sink allows direct drive of LEDs
• 6 x 16-bit general-purpose timers
• Clock Sources:
• Independent watchdog timer, clocked from the low frequency oscillator
• Internal 72 MHz oscillator with accuracy of ±2%
• On-Chip, Non-Intrusive Debugging
• Internal 24.5 MHz oscillator with ±2% accuracy
• Full memory and register inspection
• Internal 80 kHz low-frequency oscillator
• Four hardware breakpoints, single-stepping
• External CMOS clock option (up to 50 MHz)
•
Pre-programmed
UART or SMBus bootloader
• External RC oscillator (up to 3.2 MHz)
With on-chip power-on reset, voltage supply monitor, watchdog timer, and clock oscillator, the EFM8LB1 devices are truly standalone
system-on-a-chip solutions. The flash memory is reprogrammable in-circuit, providing nonvolatile data storage and allowing field upgrades of the firmware. The on-chip debugging interface (C2) allows non-intrusive (uses no on-chip resources), full speed, in-circuit
debugging using the production MCU installed in the final application. This debug logic supports inspection and modification of memory
and registers, setting breakpoints, single stepping, and run and halt commands. All analog and digital peripherals are fully functional
while debugging. Device operation is specified from 2.2 V up to a 3.6 V supply. Devices are available in 4x4 mm 32-pin QFN, 3x3 mm
24-pin QFN, 32-pin QFP, or 24-pin QSOP packages. All package options are lead-free and RoHS compliant.
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�EFM8LB1 Data Sheet
Ordering Information
2. Ordering Information
EFM8 LB1 2 F 64 E S1 – A – QFN32 R
Tape and Reel (Optional)
Package Type
Revision
SMBus Bootloader (S) and Bootloader Revision (0 or 1) (Optional)
Temperature Grade E (-40 to +105)
Flash Memory Size – 64 KB
Memory Type (Flash)
Family Feature Set
Laser Bee 1 Family
Silicon Labs EFM8 Product Line
Figure 2.1. EFM8LB1 Part Numbering
All EFM8LB1 family members have the following features:
• CIP-51 Core running up to 72 MHz
• Three Internal Oscillators (72 MHz, 24.5 MHz and 80 kHz)
• SMBus
• I2C Slave
• SPI
• 2 UARTs
• 6-Channel Programmable Counter Array (PWM, Clock Generation, Capture/Compare)
• Six 16-bit Timers
• Four Configurable Logic Units
• 14-bit Analog-to-Digital Converter with integrated multiplexer, voltage reference, temperature sensor, channel sequencer, and directto-XRAM data transfer
• Two Analog Comparators
• 16-bit CRC Unit
• Temperature range: -40 to +105 °C
In addition to these features, each part number in the EFM8LB1 family has a set of features that vary across the product line. The
product selection guide shows the features available on each family member.
Ordering Part Number
Flash Memory (kB)
RAM (Bytes)
Digital Port I/Os (Total)
ADC0 Channels
Voltage DACs
Comparator 0 Inputs
Comparator 1 Inputs
Bootloader Type
Bootloader Pins
Pb-free (RoHS Compliant)
Package
Table 2.1. Product Selection Guide
EFM8LB12F64E-C-QFN32
64
4352
29
20
4
10
9
UART
P0.4 / P0.52
Yes
QFN32
EFM8LB12F64E-C-QFP32
64
4352
28
20
4
10
9
UART
P0.4 / P0.52
Yes
QFP32
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Rev. 1.3 | 3
�EFM8LB1 Data Sheet
Ordering Part Number
Flash Memory (kB)
RAM (Bytes)
Digital Port I/Os (Total)
ADC0 Channels
Voltage DACs
Comparator 0 Inputs
Comparator 1 Inputs
Bootloader Type
Bootloader Pins
Pb-free (RoHS Compliant)
Package
Ordering Information
EFM8LB12F64E-C-QFN24
64
4352
20
12
4
6
6
UART
P0.4 / P0.52
Yes
QFN24
EFM8LB12F64E-C-QSOP24
64
4352
21
13
4
6
7
UART
P0.4 / P0.52
Yes
QSOP24
EFM8LB12F64ES0-C-QFN32
64
4352
29
20
4
10
9
SMBus
P0.2 / P0.32
Yes
QFN32
EFM8LB12F64ES0-C-QFN24
64
4352
20
12
4
6
6
SMBus
P0.2 / P0.32
Yes
QFN24
EFM8LB12F64ES1-C-QFN32
64
4352
29
20
4
10
9
SMBus
P0.2 / P0.42
Yes
QFN32
EFM8LB12F64ES1-C-QFN24
64
4352
20
12
4
6
6
SMBus
P0.2 / P0.42
Yes
QFN24
EFM8LB12F32E-C-QFN32
32
2304
29
20
4
10
9
UART
P0.4 / P0.52
Yes
QFN32
EFM8LB12F32E-C-QFP32
32
2304
28
20
4
10
9
UART
P0.4 / P0.52
Yes
QFP32
EFM8LB12F32E-C-QFN24
32
2304
20
12
4
6
6
UART
P0.4 / P0.52
Yes
QFN24
EFM8LB12F32E-C-QSOP24
32
2304
21
13
4
6
7
UART
P0.4 / P0.52
Yes
QSOP24
EFM8LB12F32ES0-C-QFN32
32
2304
29
20
4
10
9
SMBus
P0.2 / P0.32
Yes
QFN32
EFM8LB12F32ES0-C-QFN24
32
2304
20
12
4
6
6
SMBus
P0.2 / P0.32
Yes
QFN24
EFM8LB12F32ES1-C-QFN32
32
2304
29
20
4
10
9
SMBus
P0.2 / P0.42
Yes
QFN32
EFM8LB12F32ES1-C-QFN24
32
2304
20
12
4
6
6
SMBus
P0.2 / P0.42
Yes
QFN24
EFM8LB11F32E-C-QFN32
32
2304
29
20
21
10
9
UART
P0.4 / P0.52
Yes
QFN32
EFM8LB11F32E-C-QFP32
32
2304
28
20
21
10
9
UART
P0.4 / P0.52
Yes
QFP32
EFM8LB11F32E-C-QFN24
32
2304
20
12
21
6
6
UART
P0.4 / P0.52
Yes
QFN24
EFM8LB11F32E-C-QSOP24
32
2304
21
13
21
6
7
UART
P0.4 / P0.52
Yes
QSOP24
EFM8LB11F32ES0-C-QFN32
32
2304
29
20
21
10
9
SMBus
P0.2 / P0.32
Yes
QFN32
EFM8LB11F32ES0-C-QFN24
32
2304
20
12
21
6
6
SMBus
P0.2 / P0.32
Yes
QFN24
EFM8LB11F32ES1-C-QFN32
32
2304
29
20
21
10
9
SMBus
P0.2 / P0.42
Yes
QFN32
EFM8LB11F32ES1-C-QFN24
32
2304
20
12
21
6
6
SMBus
P0.2 / P0.42
Yes
QFN24
EFM8LB11F16E-C-QFN32
16
1280
29
20
21
10
9
UART
P0.4 / P0.52
Yes
QFN32
EFM8LB11F16E-C-QFP32
16
1280
28
20
21
10
9
UART
P0.4 / P0.52
Yes
QFP32
EFM8LB11F16E-C-QFN24
16
1280
20
12
21
6
6
UART
P0.4 / P0.52
Yes
QFN24
EFM8LB11F16E-C-QSOP24
16
1280
21
13
21
6
7
UART
P0.4 / P0.52
Yes
QSOP24
EFM8LB11F16ES0-C-QFN32
16
1280
29
20
21
10
9
SMBus
P0.2 / P0.32
Yes
QFN32
EFM8LB11F16ES0-C-QFN24
16
1280
20
12
21
6
6
SMBus
P0.2 / P0.32
Yes
QFN24
EFM8LB11F16ES1-C-QFN32
16
1280
29
20
21
10
9
SMBus
P0.2 / P0.42
Yes
QFN32
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Rev. 1.3 | 4
�EFM8LB1 Data Sheet
Ordering Part Number
Flash Memory (kB)
RAM (Bytes)
Digital Port I/Os (Total)
ADC0 Channels
Voltage DACs
Comparator 0 Inputs
Comparator 1 Inputs
Bootloader Type
Bootloader Pins
Pb-free (RoHS Compliant)
Package
Ordering Information
EFM8LB11F16ES1-C-QFN24
16
1280
20
12
21
6
6
SMBus
P0.2 / P0.42
Yes
QFN24
EFM8LB10F16E-C-QFN32
16
1280
29
20
0
10
9
UART
P0.4 / P0.52
Yes
QFN32
EFM8LB10F16E-C-QFP32
16
1280
28
20
0
10
9
UART
P0.4 / P0.52
Yes
QFP32
EFM8LB10F16E-C-QFN24
16
1280
20
12
0
6
6
UART
P0.4 / P0.52
Yes
QFN24
EFM8LB10F16E-C-QSOP24
16
1280
21
13
0
6
7
UART
P0.4 / P0.52
Yes
QSOP24
EFM8LB10F16ES0-C-QFN32
16
1280
29
20
0
10
9
SMBus
P0.2 / P0.32
Yes
QFN32
EFM8LB10F16ES0-C-QFN24
16
1280
20
12
0
6
6
SMBus
P0.2 / P0.32
Yes
QFN24
EFM8LB10F16ES1-C-QFN32
16
1280
29
20
0
10
9
SMBus
P0.2 / P0.42
Yes
QFN32
EFM8LB10F16ES1-C-QFN24
16
1280
20
12
0
6
6
SMBus
P0.2 / P0.42
Yes
QFN24
Note:
1. DAC0 and DAC1 are enabled on devices with 2 DACs available.
2. See 3.10 Bootloader for more information on the bootloader types and pin usage.
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Rev. 1.3 | 5
�Table of Contents
1. Feature List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
2. Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
3. System Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
3.1 Introduction .
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. 8
3.2 Power .
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. 9
3.3 I/O .
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. 9
3.4 Clocking .
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.10
3.5 Counters/Timers and PWM .
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.10
3.6 Communications and Other Digital Peripherals .
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.11
3.7 Analog.
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.14
3.8 Reset Sources .
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.15
3.9 Debugging .
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.15
3.10 Bootloader .
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.16
4. Electrical Specifications
. . . . . . . . . . . . . . . . . . . . . . . . . . 18
4.1 Electrical Characteristics . . . . . .
4.1.1 Recommended Operating Conditions .
4.1.2 Power Consumption. . . . . . .
4.1.3 Reset and Supply Monitor . . . . .
4.1.4 Flash Memory . . . . . . . . .
4.1.5 Power Management Timing . . . .
4.1.6 Internal Oscillators . . . . . . .
4.1.7 External Clock Input . . . . . . .
4.1.8 External Oscillator . . . . . . .
4.1.9 ADC . . . . . . . . . . . .
4.1.10 Voltage Reference . . . . . . .
4.1.11 Temperature Sensor . . . . . .
4.1.12 1.8 V Internal LDO Voltage Regulator
4.1.13 DACs . . . . . . . . . . .
4.1.14 Comparators . . . . . . . . .
4.1.15 Configurable Logic . . . . . . .
4.1.16 Port I/O . . . . . . . . . .
4.1.17 SMBus . . . . . . . . . . .
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.18
.18
.19
.21
.21
.22
.22
.23
.23
.24
.27
.28
.28
.29
.30
.31
.32
.33
4.2 Thermal Conditions .
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.35
4.3 Absolute Maximum Ratings.
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.36
5. Typical Connection Diagrams
. . . . . . . . . . . . . . . . . . . . . . . . 37
5.1 Power .
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.37
5.2 Debug .
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.38
5.3 Other Connections.
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.38
6. Pin Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
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Rev. 1.3 | 6
�6.1 EFM8LB1x-QFN32 Pin Definitions .
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.39
6.2 EFM8LB1x-QFP32 Pin Definitions .
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.44
6.3 EFM8LB1x-QFN24 Pin Definitions .
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.49
6.4 EFM8LB1x-QSOP24 Pin Definitions .
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7. QFN32 Package Specifications. . . . . . . . . . . . . . . . . . . . . . . .
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7.1 Package Dimensions .
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7.3 Package Marking .
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8. QFP32 Package Specifications . . . . . . . . . . . . . . . . . . . . . . . .
63
8.1 Package Dimensions .
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8.3 Package Marking .
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9. QFN24 Package Specifications. . . . . . . . . . . . . . . . . . . . . . . .
67
9.1 Package Dimensions .
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9.3 Package Marking .
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10. QSOP24 Package Specifications
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10.1 Package Dimensions .
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10.3 Package Marking.
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11. Revision History. . . . . . . . . . . . . . . . . . . . . . . . . . . . .
75
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Rev. 1.3 | 7
�EFM8LB1 Data Sheet
System Overview
3. System Overview
3.1 Introduction
Debug /
C2D
Programming
Hardware
C2CK/RSTb
CIP-51 8051 Controller
Core
Port I/O Configuration
Digital Peripherals
UART0
64 KB ISP Flash
Program Memory
Reset
Power-On
Reset
VIO
UART1
Timers 0,
1, 2, 3, 4, 5
256 Byte SRAM
Priority
Crossbar
Decoder
6-ch PCA
Supply
Monitor
Power
Net
Voltage
Regulator
I2C /
SMBus
SPI
Independent
Watchdog
Timer
GND
SFR
Bus
Config.
Logic
Units (4)
System Clock
Configuration
Low Freq.
Oscillator
EXTCLK
CMOS Clock
Input
EXTOSC
External
RC Oscillator
72 MHz 2%
Oscillator
24.5 MHz 2%
Oscillator
P0.n
Port 1
Drivers
P1.n
Port 2
Drivers
P2.n
Port 3
Drivers
P3.n
CRC
SYSCLK
Crossbar
Control
Analog Peripherals
Internal
Reference
VDD
4 12-bit
DACs
VREF
VDD
14/12/10bit ADC
AMUX
VDD
I2C Slave
4096 Byte XRAM
Port 0
Drivers
Temp
Sensor
+
-+
2 Comparators
Figure 3.1. Detailed EFM8LB1 Block Diagram
This section describes the EFM8LB1 family at a high level.
For more information on the device packages and pinout, electrical specifications, and typical connection diagrams, see the EFM8LB1
Data Sheet. For more information on each module including register definitions, see the EFM8LB1 Reference Manual. For more information on any errata, see the EFM8LB1 Errata.
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Rev. 1.3 | 8
�EFM8LB1 Data Sheet
System Overview
3.2 Power
All internal circuitry draws power from the VDD supply pin. External I/O pins are powered from the VIO supply voltage (or VDD on devices without a separate VIO connection), while most of the internal circuitry is supplied by an on-chip LDO regulator. Control over the
device power can be achieved by enabling/disabling individual peripherals as needed. Each analog peripheral can be disabled when
not in use and placed in low power mode. Digital peripherals, such as timers and serial buses, have their clocks gated off and draw little
power when they are not in use.
Table 3.1. Power Modes
Power Mode
Normal
Idle
Suspend
Stop
Snooze
Shutdown
Details
Mode Entry
Wake-Up Sources
Set IDLE bit in PCON0
Any interrupt
Core and all peripherals clocked and fully operational
• Core halted
• All peripherals clocked and fully operational
• Code resumes execution on wake event
•
•
•
•
•
Core and peripheral clocks halted
HFOSC0 and HFOSC1 oscillators stopped
Regulator in normal bias mode for fast wake
Timer 3 and 4 may clock from LFOSC0
Code resumes execution on wake event
1. Switch SYSCLK to
HFOSC0
2. Set SUSPEND bit in
PCON1
•
•
•
•
•
Timer 4 Event
SPI0 Activity
I2C0 Slave Activity
Port Match Event
Comparator 0 Falling
Edge
• CLUn Interrupt-Enabled
Event
• All internal power nets shut down
• Pins retain state
• Exit on any reset source
1. Clear STOPCF bit in
REG0CN
2. Set STOP bit in
PCON0
Any reset source
• Core and peripheral clocks halted
• HFOSC0 and HFOSC1 oscillators stopped
• Regulator in low bias current mode for energy savings
• Timer 3 and 4 may clock from LFOSC0
• Code resumes execution on wake event
1. Switch SYSCLK to
HFOSC0
2. Set SNOOZE bit in
PCON1
•
•
•
•
•
• All internal power nets shut down
• Pins retain state
• Exit on pin or power-on reset
1. Set STOPCF bit in
REG0CN
2. Set STOP bit in
PCON0
• RSTb pin reset
• Power-on reset
Timer 4 Event
SPI0 Activity
I2C0 Slave Activity
Port Match Event
Comparator 0 Falling
Edge
• CLUn Interrupt-Enabled
Event
3.3 I/O
Digital and analog resources are externally available on the device’s multi-purpose I/O pins. Port pins P0.0-P2.3 can be defined as general-purpose I/O (GPIO), assigned to one of the internal digital resources through the crossbar or dedicated channels, or assigned to an
analog function. Port pins P2.4 to P3.7 can be used as GPIO. Additionally, the C2 Interface Data signal (C2D) is shared with P3.0 or
P3.7, depending on the package option.
The port control block offers the following features:
• Up to 29 multi-functions I/O pins, supporting digital and analog functions.
• Flexible priority crossbar decoder for digital peripheral assignment.
• Two drive strength settings for each port.
• State retention feature allows pins to retain configuration through most reset sources.
• Two direct-pin interrupt sources with dedicated interrupt vectors (INT0 and INT1).
• Up to 24 direct-pin interrupt sources with shared interrupt vector (Port Match).
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Rev. 1.3 | 9
�EFM8LB1 Data Sheet
System Overview
3.4 Clocking
The CPU core and peripheral subsystem may be clocked by both internal and external oscillator resources. By default, the system
clock comes up running from the 24.5 MHz oscillator divided by 8.
The clock control system offers the following features:
• Provides clock to core and peripherals.
• 24.5 MHz internal oscillator (HFOSC0), accurate to ±2% over supply and temperature corners.
• 72 MHz internal oscillator (HFOSC1), accurate to ±2% over supply and temperature corners.
• 80 kHz low-frequency oscillator (LFOSC0).
• External RC and CMOS clock options (EXTCLK and EXTOSC).
• Clock divider with eight settings for flexible clock scaling:
• Divide the selected clock source by 1, 2, 4, 8, 16, 32, 64, or 128.
• HFOSC0 and HFOSC1 include 1.5x pre-scalers for further flexibility.
3.5 Counters/Timers and PWM
Programmable Counter Array (PCA0)
The programmable counter array (PCA) provides multiple channels of enhanced timer and PWM functionality while requiring less CPU
intervention than standard counter/timers. The PCA consists of a dedicated 16-bit counter/timer and one 16-bit capture/compare module for each channel. The counter/timer is driven by a programmable timebase that has flexible external and internal clocking options.
Each capture/compare module may be configured to operate independently in one of five modes: Edge-Triggered Capture, Software
Timer, High-Speed Output, Frequency Output, or Pulse-Width Modulated (PWM) Output. Each capture/compare module has its own
associated I/O line (CEXn) which is routed through the crossbar to port I/O when enabled.
•
•
•
•
•
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•
•
16-bit time base
Programmable clock divisor and clock source selection
Up to six independently-configurable channels
8, 9, 10, 11 and 16-bit PWM modes (center or edge-aligned operation)
Output polarity control
Frequency output mode
Capture on rising, falling or any edge
Compare function for arbitrary waveform generation
Software timer (internal compare) mode
Can accept hardware “kill” signal from comparator 0 or comparator 1
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Rev. 1.3 | 10
�EFM8LB1 Data Sheet
System Overview
Timers (Timer 0, Timer 1, Timer 2, Timer 3, Timer 4, and Timer 5)
Several counter/timers are included in the device: two are 16-bit counter/timers compatible with those found in the standard 8051, and
the rest are 16-bit auto-reload timers for timing peripherals or for general purpose use. These timers can be used to measure time intervals, count external events and generate periodic interrupt requests. Timer 0 and Timer 1 are nearly identical and have four primary
modes of operation. The other timers offer both 16-bit and split 8-bit timer functionality with auto-reload and capture capabilities.
Timer 0 and Timer 1 include the following features:
• Standard 8051 timers, supporting backwards-compatibility with firmware and hardware.
• Clock sources include SYSCLK, SYSCLK divided by 12, 4, or 48, the External Clock divided by 8, or an external pin.
• 8-bit auto-reload counter/timer mode
• 13-bit counter/timer mode
• 16-bit counter/timer mode
• Dual 8-bit counter/timer mode (Timer 0)
Timer 2, Timer 3, Timer 4, and Timer 5 are 16-bit timers including the following features:
• Clock sources for all timers include SYSCLK, SYSCLK divided by 12, or the External Clock divided by 8
• LFOSC0 divided by 8 may be used to clock Timer 3 and Timer 4 in active or suspend/snooze power modes
• Timer 4 is a low-power wake source, and can be chained together with Timer 3
• 16-bit auto-reload timer mode
• Dual 8-bit auto-reload timer mode
• External pin capture
• LFOSC0 capture
• Comparator 0 capture
• Configurable Logic output capture
Watchdog Timer (WDT0)
The device includes a programmable watchdog timer (WDT) running off the low-frequency oscillator. A WDT overflow forces the MCU
into the reset state. To prevent the reset, the WDT must be restarted by application software before overflow. If the system experiences
a software or hardware malfunction preventing the software from restarting the WDT, the WDT overflows and causes a reset. Following
a reset, the WDT is automatically enabled and running with the default maximum time interval. If needed, the WDT can be disabled by
system software or locked on to prevent accidental disabling. Once locked, the WDT cannot be disabled until the next system reset.
The state of the RST pin is unaffected by this reset.
The Watchdog Timer has the following features:
• Programmable timeout interval
• Runs from the low-frequency oscillator
• Lock-out feature to prevent any modification until a system reset
3.6 Communications and Other Digital Peripherals
Universal Asynchronous Receiver/Transmitter (UART0)
UART0 is an asynchronous, full duplex serial port offering modes 1 and 3 of the standard 8051 UART. Enhanced baud rate support
allows a wide range of clock sources to generate standard baud rates. Received data buffering allows UART0 to start reception of a
second incoming data byte before software has finished reading the previous data byte.
The UART module provides the following features:
• Asynchronous transmissions and receptions.
• Baud rates up to SYSCLK/2 (transmit) or SYSCLK/8 (receive).
• 8- or 9-bit data.
• Automatic start and stop generation.
• Single-byte FIFO on transmit and receive.
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Rev. 1.3 | 11
�EFM8LB1 Data Sheet
System Overview
Universal Asynchronous Receiver/Transmitter (UART1)
UART1 is an asynchronous, full duplex serial port offering a variety of data formatting options. A dedicated baud rate generator with a
16-bit timer and selectable prescaler is included, which can generate a wide range of baud rates. A received data FIFO allows UART1
to receive multiple bytes before data is lost and an overflow occurs.
UART1 provides the following features:
• Asynchronous transmissions and receptions
• Dedicated baud rate generator supports baud rates up to SYSCLK/2 (transmit) or SYSCLK/8 (receive)
• 5, 6, 7, 8, or 9 bit data
• Automatic start and stop generation
• Automatic parity generation and checking
• Single-byte buffer on transmit and receive
• Auto-baud detection
• LIN break and sync field detection
• CTS / RTS hardware flow control
Serial Peripheral Interface (SPI0)
The serial peripheral interface (SPI) module provides access to a flexible, full-duplex synchronous serial bus. The SPI can operate as a
master or slave device in both 3-wire or 4-wire modes, and supports multiple masters and slaves on a single SPI bus. The slave-select
(NSS) signal can be configured as an input to select the SPI in slave mode, or to disable master mode operation in a multi-master
environment, avoiding contention on the SPI bus when more than one master attempts simultaneous data transfers. NSS can also be
configured as a firmware-controlled chip-select output in master mode, or disabled to reduce the number of pins required. Additional
general purpose port I/O pins can be used to select multiple slave devices in master mode.
•
•
•
•
•
•
•
•
Supports 3- or 4-wire master or slave modes
Supports external clock frequencies up to 12 Mbps in master or slave mode
Support for all clock phase and polarity modes
8-bit programmable clock rate (master)
Programmable receive timeout (slave)
Two byte FIFO on transmit and receive
Can operate in suspend or snooze modes and wake the CPU on reception of a byte
Support for multiple masters on the same data lines
System Management Bus / I2C (SMB0)
The SMBus I/O interface is a two-wire, bi-directional serial bus. The SMBus is compliant with the System Management Bus Specification, version 1.1, and compatible with the I2C serial bus.
The SMBus module includes the following features:
• Standard (up to 100 kbps) and Fast (400 kbps) transfer speeds
• Support for master, slave, and multi-master modes
• Hardware synchronization and arbitration for multi-master mode
• Clock low extending (clock stretching) to interface with faster masters
• Hardware support for 7-bit slave and general call address recognition
• Firmware support for 10-bit slave address decoding
• Ability to inhibit all slave states
• Programmable data setup/hold times
• Transmit and receive FIFOs (one byte) to help increase throughput in faster applications
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�EFM8LB1 Data Sheet
System Overview
I2C Slave (I2CSLAVE0)
The I2C Slave interface is a 2-wire, bidirectional serial bus that is compatible with the I2C Bus Specification 3.0. It is capable of transferring in high-speed mode (HS-mode) at speeds of up to 3.4 Mbps. Firmware can write to the I2C interface, and the I2C interface can
autonomously control the serial transfer of data. The interface also supports clock stretching for cases where the core may be temporarily prohibited from transmitting a byte or processing a received byte during an I2C transaction. This module operates only as an I2C
slave device.
The I2C module includes the following features:
• Standard (up to 100 kbps), Fast (400 kbps), Fast Plus (1 Mbps), and High-speed (3.4 Mbps) transfer speeds
• Support for slave mode only
• Clock low extending (clock stretching) to interface with faster masters
• Hardware support for 7-bit slave address recognition
• Transmit and receive FIFOs (two byte) to help increase throughput in faster applications
• Hardware support for multiple slave addresses with the option to save the matching address in the receive FIFO
16-bit CRC (CRC0)
The cyclic redundancy check (CRC) module performs a CRC using a 16-bit polynomial. CRC0 accepts a stream of 8-bit data and posts
the 16-bit result to an internal register. In addition to using the CRC block for data manipulation, hardware can automatically CRC the
flash contents of the device.
The CRC module is designed to provide hardware calculations for flash memory verification and communications protocols. The CRC
module supports the standard CCITT-16 16-bit polynomial (0x1021), and includes the following features:
• Support for CCITT-16 polynomial
• Byte-level bit reversal
• Automatic CRC of flash contents on one or more 256-byte blocks
• Initial seed selection of 0x0000 or 0xFFFF
Configurable Logic Units (CLU0, CLU1, CLU2, and CLU3)
The Configurable Logic block consists of multiple Configurable Logic Units (CLUs). CLUs are flexible logic functions which may be used
for a variety of digital functions, such as replacing system glue logic, aiding in the generation of special waveforms, or synchronizing
system event triggers.
• Four configurable logic units (CLUs), with direct-pin and internal logic connections
• Each unit supports 256 different combinatorial logic functions (AND, OR, XOR, muxing, etc.) and includes a clocked flip-flop for synchronous operations
• Units may be operated synchronously or asynchronously
• May be cascaded together to perform more complicated logic functions
• Can operate in conjunction with serial peripherals such as UART and SPI or timing peripherals such as timers and PCA channels
• Can be used to synchronize and trigger multiple on-chip resources (ADC, DAC, Timers, etc.)
• Asynchronous output may be used to wake from low-power states
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Rev. 1.3 | 13
�EFM8LB1 Data Sheet
System Overview
3.7 Analog
14/12/10-Bit Analog-to-Digital Converter (ADC0)
The ADC is a successive-approximation-register (SAR) ADC with 14-, 12-, and 10-bit modes, integrated track-and hold and a programmable window detector. The ADC is fully configurable under software control via several registers. The ADC may be configured to
measure different signals using the analog multiplexer. The voltage reference for the ADC is selectable between internal and external
reference sources.
•
•
•
•
•
•
•
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•
•
Up to 20 external inputs
Single-ended 14-bit, 12-bit and 10-bit modes
Supports an output update rate of up to 1 Msps in 12-bit mode
Channel sequencer logic with direct-to-XDATA output transfers
Operation in a low power mode at lower conversion speeds
Asynchronous hardware conversion trigger, selectable between software, external I/O and internal timer and configurable logic sources
Output data window comparator allows automatic range checking
Support for output data accumulation
Conversion complete and window compare interrupts supported
Flexible output data formatting
Includes a fully-internal fast-settling 1.65 V reference and an on-chip precision 2.4 / 1.2 V reference, with support for using the supply as the reference, an external reference and signal ground
Integrated factory-calibrated temperature sensor
12-Bit Digital-to-Analog Converters (DAC0, DAC1, DAC2, DAC3)
The DAC modules are 12-bit Digital-to-Analog Converters with the capability to synchronize multiple outputs together. The DACs are
fully configurable under software control. The voltage reference for the DACs is selectable between internal and external reference
sources.
•
•
•
•
•
•
•
•
Voltage output with 12-bit performance
Hardware conversion trigger, selectable between software, external I/O and internal timer and configurable logic sources
Outputs may be configured to persist through reset and maintain output state to avoid system disruption
Multiple DAC outputs can be synchronized together
DAC pairs (DAC0 and 1 or DAC2 and 3) support complementary output waveform generation
Outputs may be switched between two levels according to state of configurable logic / PWM input trigger
Flexible input data formatting
Supports references from internal supply, on-chip precision reference, or external VREF pin
Low Current Comparators (CMP0, CMP1)
An analog comparator is used to compare the voltage of two analog inputs, with a digital output indicating which input voltage is higher.
External input connections to device I/O pins and internal connections are available through separate multiplexers on the positive and
negative inputs. Hysteresis, response time, and current consumption may be programmed to suit the specific needs of the application.
The comparator includes the following features:
• Up to 10 (CMP0) or 9 (CMP1) external positive inputs
• Up to 10 (CMP0) or 9 (CMP1) external negative inputs
• Additional input options:
• Internal connection to LDO output
• Direct connection to GND
• Direct connection to VDD
• Dedicated 6-bit reference DAC
• Synchronous and asynchronous outputs can be routed to pins via crossbar
• Programmable hysteresis between 0 and ±20 mV
• Programmable response time
• Interrupts generated on rising, falling, or both edges
• PWM output kill feature
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Rev. 1.3 | 14
�EFM8LB1 Data Sheet
System Overview
3.8 Reset Sources
Reset circuitry allows the controller to be easily placed in a predefined default condition. On entry to this reset state, the following occur:
• The core halts program execution.
• Module registers are initialized to their defined reset values unless the bits reset only with a power-on reset.
• External port pins are forced to a known state.
• Interrupts and timers are disabled.
All registers are reset to the predefined values noted in the register descriptions unless the bits only reset with a power-on reset. The
contents of RAM are unaffected during a reset; any previously stored data is preserved as long as power is not lost. By default, the Port
I/O latches are reset to 1 in open-drain mode, with weak pullups enabled during and after the reset. Optionally, firmware may configure
the port I/O, DAC outputs, and precision reference to maintain state through system resets other than power-on resets. For Supply
Monitor and power-on resets, the RSTb pin is driven low until the device exits the reset state. On exit from the reset state, the program
counter (PC) is reset, and the system clock defaults to an internal oscillator. The Watchdog Timer is enabled, and program execution
begins at location 0x0000.
Reset sources on the device include the following:
• Power-on reset
• External reset pin
• Comparator reset
• Software-triggered reset
• Supply monitor reset (monitors VDD supply)
• Watchdog timer reset
• Missing clock detector reset
• Flash error reset
3.9 Debugging
The EFM8LB1 devices include an on-chip Silicon Labs 2-Wire (C2) debug interface to allow flash programming and in-system debugging with the production part installed in the end application. The C2 interface uses a clock signal (C2CK) and a bi-directional C2 data
signal (C2D) to transfer information between the device and a host system. See the C2 Interface Specification for details on the C2
protocol.
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Rev. 1.3 | 15
�EFM8LB1 Data Sheet
System Overview
3.10 Bootloader
All devices come pre-programmed with a UART0 bootloader or an SMBus bootloader. These bootloaders reside in the code security
page, which is the last page of code flash; they can be erased if they are not needed.
The byte before the Lock Byte is the Bootloader Signature Byte. Setting this byte to a value of 0xA5 indicates the presence of the bootloader in the system. Any other value in this location indicates that the bootloader is not present in flash.
When a bootloader is present, the device will jump to the bootloader vector after any reset, allowing the bootloader to run. The bootloader then determines if the device should stay in bootload mode or jump to the reset vector located at 0x0000. When the bootloader
is not present, the device will jump to the reset vector of 0x0000 after any reset.
Silicon Labs recommends the bootloader be disabled and the flash memory locked after the production programming step in applications where code security is a concern. More information about the factory bootloader protocol, usage, customization and best practices
can be found in AN945: EFM8 Factory Bootloader User Guide. Application notes can be found on the Silicon Labs website (www.silabs.com/8bit-appnotes) or within Simplicity Studio by using the [Application Notes] tile.
0xFFC0
0xFFBF
0xFC00
Read-Only
64 Bytes
Reserved
0xFBFF
Lock Byte
0xFBFE
Bootloader Signature Byte
0xFBFD
Code Security Page
0xFA00
0xF9FF
(1 x 512 Byte pages)
Bootloader
0xFFFF
Bootloader Vector
62 KB Code
(124 x 512 Byte pages)
0x0000
Reset Vector
Figure 3.2. Flash Memory Map with Bootloader — 62.5 KB Devices
Table 3.2. Summary of Pins for Bootloader Communication
Bootloader
UART
Pins for Bootload Communication
TX – P0.4
RX – P0.5
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Rev. 1.3 | 16
�EFM8LB1 Data Sheet
System Overview
Bootloader
Pins for Bootload Communication
SMBus - S0 part numbers
P0.2 – SDA1
P0.3 – SCL1
SMBus - S1 part numbers
P0.2 – SDA1
P0.4 – SCL1
Note:
1. The STK uses these pins for another purpose, so there is a special SMBus bootloader build for the STK only included in AN945:
EFM8 Factory Bootloader User Guide that uses P1.2 (SDA) and P1.3 (SCL).
Table 3.3. Summary of Pins for Bootload Mode Entry
Device Package
Pin for Bootload Mode Entry
QFN32
P3.7 / C2D
QFP32
P3.7 / C2D
QFN24
P3.0 / C2D
QSOP24
P3.0 / C2D
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Rev. 1.3 | 17
�EFM8LB1 Data Sheet
Electrical Specifications
4. Electrical Specifications
4.1 Electrical Characteristics
All electrical parameters in all tables are specified under the conditions listed in Table 4.1 Recommended Operating Conditions on page
18, unless stated otherwise.
4.1.1 Recommended Operating Conditions
Table 4.1. Recommended Operating Conditions
Parameter
Symbol
Operating Supply Voltage on VDD
VDD
Operating Supply Voltage on VIO2, VIO
3
System Clock Frequency
fSYSCLK
Operating Ambient Temperature
TA
Test Condition
Min
Typ
Max
Unit
2.2
—
3.6
V
2.2
—
VDD
V
1.713
—
VDD
V
0
—
73.5
MHz
-40
—
105
°C
Note:
1. All voltages with respect to GND
2. In certain package configurations, the VIO and VDD supplies are bonded to the same pin.
3. I/O have reduced current drive/sink capabilities at lower VIO levels. See 4.1.16 Port I/O for additional information.
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Rev. 1.3 | 18
�EFM8LB1 Data Sheet
Electrical Specifications
4.1.2 Power Consumption
Table 4.2. Power Consumption
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
FSYSCLK = 72 MHz (HFOSC1)2
—
12.9
15
mA
FSYSCLK = 24.5 MHz (HFOSC0)2
—
4.2
5
mA
FSYSCLK = 1.53 MHz (HFOSC0)2
—
625
1050
μA
FSYSCLK = 80 kHz3
—
155
575
μA
FSYSCLK = 72 MHz (HFOSC1)2
—
9.6
11.1
mA
FSYSCLK = 24.5 MHz (HFOSC0)2
—
3.14
3.8
mA
FSYSCLK = 1.53 MHz (HFOSC0)2
—
520
950
μA
FSYSCLK = 80 kHz3
—
135
550
μA
LFO Running
—
125
545
μA
LFO Stopped
—
120
535
μA
LFO Running
—
23
430
μA
LFO Stopped
—
19
425
μA
Digital Core Supply Current
Normal Mode-Full speed with code IDD
executing from flash
Idle Mode-Core halted with peripherals running
IDD
Suspend Mode-Core halted and
high frequency clocks stopped,
Supply monitor off.
IDD
Snooze Mode-Core halted and
high frequency clocks stopped.
Regulator in low-power state, Supply monitor off.
IDD
Stop Mode—Core halted and all
clocks stopped,Internal LDO On,
Supply monitor off.
IDD
—
120
535
μA
Shutdown Mode—Core halted and
all clocks stopped,Internal LDO
Off, Supply monitor off.
IDD
—
0.2
2.1
μA
—
120
135
μA
—
1285
1340
μA
—
3.7
6
μA
Analog Peripheral Supply Currents
High-Frequency Oscillator 0
IHFOSC0
Operating at 24.5 MHz,
TA = 25 °C
High-Frequency Oscillator 1
IHFOSC1
Operating at 72 MHz,
TA = 25 °C
Low-Frequency Oscillator
ILFOSC
Operating at 80 kHz,
TA = 25 °C
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Rev. 1.3 | 19
�EFM8LB1 Data Sheet
Electrical Specifications
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
ADC04
IADC
High Speed Mode
—
1275
1700
μA
—
390
530
μA
High Speed Mode
—
700
790
μA
Low Power Mode
—
170
210
μA
1 Msps, 12-bit conversions
Normal bias settings
VDD = 3.0 V
Low Power Mode
350 ksps, 12-bit conversions
Low power bias settings
VDD = 3.0 V
Internal ADC0 Reference5
IVREFFS
On-chip Precision Reference
IVREFP
—
75
—
µA
Temperature Sensor
ITSENSE
—
68
120
μA
Digital-to-Analog Converters
(DAC0, DAC1, DAC2, DAC3)6
IDAC
—
125
—
µA
Comparators (CMP0, CMP1)
ICMP
CPMD = 11
—
0.5
—
μA
CPMD = 10
—
3
—
μA
CPMD = 01
—
10
—
μA
CPMD = 00
—
25
—
μA
Comparator Reference7
ICPREF
—
24
—
μA
Voltage Supply Monitor (VMON0)
IVMON
—
15
20
μA
Note:
1. Currents are additive. For example, where IDD is specified and the mode is not mutually exclusive, enabling the functions increases supply current by the specified amount.
2. Includes supply current from internal LDO regulator, supply monitor, and High Frequency Oscillator.
3. Includes supply current from internal LDO regulator, supply monitor, and Low Frequency Oscillator.
4. ADC0 power excludes internal reference supply current.
5. The internal reference is enabled as-needed when operating the ADC in low power mode. Total ADC + Reference current will
depend on sampling rate.
6. DAC supply current for each enabled DA and not including external load on pin.
7. This value is the current sourced from the pin or supply selected as the full-scale reference to the comparator DAC.
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Rev. 1.3 | 20
�EFM8LB1 Data Sheet
Electrical Specifications
4.1.3 Reset and Supply Monitor
Table 4.3. Reset and Supply Monitor
Parameter
Symbol
VDD Supply Monitor Threshold
VVDDM
Power-On Reset (POR) Threshold
VPOR
Test Condition
Min
Typ
Max
Unit
1.95
2.05
2.15
V
Rising Voltage on VDD
—
1.4
—
V
Falling Voltage on VDD
0.75
—
1.36
V
VDD Ramp Time
tRMP
Time to VDD > 2.2 V
10
—
—
μs
Reset Delay from POR
tPOR
Relative to VDD > VPOR
3
10
31
ms
Time between release of reset
source and code execution
—
50
—
μs
15
—
—
μs
—
0.625
1.2
ms
Reset Delay from non-POR source tRST
RST Low Time to Generate Reset
tRSTL
Missing Clock Detector Response
Time (final rising edge to reset)
tMCD
Missing Clock Detector Trigger
Frequency
FMCD
—
7.5
13.5
kHz
VDD Supply Monitor Turn-On Time tMON
—
2
—
μs
Min
Typ
Max
Units
19
20
21
μs
5.2
5.35
5.5
ms
VDD Voltage During Programming3 VPROG
2.2
—
3.6
V
Endurance (Write/Erase Cycles)
NWE
20k
100k
—
Cycles
CRC Calculation Time
tCRC
—
5.5
—
µs
FSYSCLK >1 MHz
4.1.4 Flash Memory
Table 4.4. Flash Memory
Parameter
Symbol
Test Condition
Write Time1 ,2
tWRITE
One Byte,
FSYSCLK = 24.5 MHz
Erase Time1 ,2
tERASE
One Page,
FSYSCLK = 24.5 MHz
One 256-Byte Block
SYSCLK = 48 MHz
Note:
1. Does not include sequencing time before and after the write/erase operation, which may be multiple SYSCLK cycles.
2. The internal High-Frequency Oscillator 0 has a programmable output frequency, which is factory programmed to 24.5 MHz. If
user firmware adjusts the oscillator speed, it must be between 22 and 25 MHz during any flash write or erase operation. It is
recommended to write the HFO0CAL register back to its reset value when writing or erasing flash.
3. Flash can be safely programmed at any voltage above the supply monitor threshold (VVDDM).
4. Data Retention Information is published in the Quarterly Quality and Reliability Report.
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Rev. 1.3 | 21
�EFM8LB1 Data Sheet
Electrical Specifications
4.1.5 Power Management Timing
Table 4.5. Power Management Timing
Parameter
Symbol
Idle Mode Wake-up Time
tIDLEWK
Suspend Mode Wake-up Time
Snooze Mode Wake-up Time
Test Condition
tSUS-
SYSCLK = HFOSC0
PENDWK
CLKDIV = 0x00
tSLEEPWK
SYSCLK = HFOSC0
Min
Typ
Max
Units
2
—
3
SYSCLKs
—
170
—
ns
—
12
—
µs
Min
Typ
Max
Unit
CLKDIV = 0x00
4.1.6 Internal Oscillators
Table 4.6. Internal Oscillators
Parameter
Symbol
Test Condition
High Frequency Oscillator 0 (24.5 MHz)
Oscillator Frequency
fHFOSC0
Full Temperature and Supply
Range
24
24.5
25
MHz
Power Supply Sensitivity
PSSHFOS
TA = 25 °C
—
0.5
—
%/V
—
40
—
ppm/°C
70.5
72
73.5
MHz
—
300
—
ppm/V
TSHFOSC1 VDD = 3.0 V
—
103
—
ppm/°C
Oscillator Frequency
fLFOSC
75
80
85
kHz
Power Supply Sensitivity
PSSLFOSC TA = 25 °C
—
0.05
—
%/V
Temperature Sensitivity
TSLFOSC
—
65
—
ppm/°C
C0
Temperature Sensitivity
TSHFOSC0 VDD = 3.0 V
High Frequency Oscillator 1 (72 MHz)
Oscillator Frequency
fHFOSC1
Full Temperature and Supply
Range
Power Supply Sensitivity
PSSHFOS
TA = 25 °C
C1
Temperature Sensitivity
Low Frequency Oscillator (80 kHz)
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Full Temperature and Supply
Range
VDD = 3.0 V
Rev. 1.3 | 22
�EFM8LB1 Data Sheet
Electrical Specifications
4.1.7 External Clock Input
Table 4.7. External Clock Input
Parameter
Symbol
External Input CMOS Clock
Test Condition
Min
Typ
Max
Unit
fCMOS
0
—
50
MHz
External Input CMOS Clock High
Time
tCMOSH
9
—
—
ns
External Input CMOS Clock Low
Time
tCMOSL
9
—
—
ns
Frequency (at EXTCLK pin)
4.1.8 External Oscillator
Table 4.8. External Oscillator
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Frequency
fEXTOSC
XFCN = 000
0.02
—
25
kHz
XFCN = 001
25
—
50
kHz
XFCN = 010
50
—
100
kHz
XFCN = 011
100
—
200
kHz
XFCN = 100
200
—
400
kHz
XFCN = 101
400
—
800
kHz
XFCN = 110
800
—
1600
kHz
XFCN = 111
1.6
—
3.2
MHz
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�EFM8LB1 Data Sheet
Electrical Specifications
4.1.9 ADC
Table 4.9. ADC
Parameter
Symbol
Test Condition
Resolution
Nbits
14 Bit Mode
14
Bits
12 Bit Mode
12
Bits
10 Bit Mode
10
Bits
Throughput Rate
fS
(High Speed Mode)
Throughput Rate
fS
(Low Power Mode)
Tracking Time
tTRK
Power-On Time
tPWR
SAR Clock Frequency
fSAR
Conversion Time2
tCNV
Min
Typ
Max
Unit
14 Bit Mode
—
—
900
ksps
12 Bit Mode
—
—
1
Msps
10 Bit Mode
—
—
1.125
Msps
14 Bit Mode
—
—
320
ksps
12 Bit Mode
—
—
340
ksps
10 Bit Mode
—
—
360
ksps
High Speed Mode
217.81
—
—
ns
Low Power Mode
450
—
—
ns
1.2
—
—
μs
High Speed Mode
—
—
18.36
MHz
Low Power Mode
—
—
12.25
MHz
14-Bit Conversion,
0.81
μs
0.7
μs
0.59
μs
SAR Clock =18 MHz,
System Clock = 72 MHz.
12-Bit Conversion,
SAR Clock =18 MHz,
System Clock = 72 MHz.
10-Bit Conversion,
SAR Clock =18 MHz,
System Clock = 72 MHz.
Sample/Hold Capacitor
Input Pin Capacitance
Input Mux Impedance
CSAR
CIN
RMUX
Gain = 1
—
5.2
—
pF
Gain = 0.75
—
3.9
—
pF
Gain = 0.5
—
2.6
—
pF
Gain = 0.25
—
1.3
—
pF
High Quality Input
—
20
—
pF
Normal Input
—
20
—
pF
High Quality Input
—
330
—
Ω
Normal Input
—
550
—
Ω
Voltage Reference Range
VREF
1
—
VIO
V
Input Voltage Range3
VIN
0
—
VREF /
Gain
V
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Rev. 1.3 | 24
�EFM8LB1 Data Sheet
Electrical Specifications
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Power Supply Rejection Ratio
PSRRADC At 1 kHz
—
66
—
dB
—
43
—
dB
14 Bit Mode
-3.54
-1.2 / +5
8.54
LSB
12 Bit Mode
-1.9
-0.35 / +1
1.9
LSB
10 Bit Mode
-0.6
±0.2
0.6
LSB
14 Bit Mode
-14
±1
2.54
LSB
12 Bit Mode
-0.9
±0.3
0.9
LSB
10 Bit Mode
-0.5
±0.2
0.5
LSB
14 Bit Mode
-84
-2.5
84
LSB
12 Bit Mode
-2
0
2
LSB
10 Bit Mode
-1
0
1
LSB
—
0.011
—
LSB/°C
14 Bit Mode
-154
—
154
LSB
12 Bit Mode
-2.6
—
2.6
LSB
10 Bit Mode
-1.1
—
1.1
LSB
At 1 MHz
DC Performance
Integral Nonlinearity
Differential Nonlinearity (Guaranteed Monotonic)
Offset Error5
INL
DNL
EOFF
Offset Temperature Coefficient
TCOFF
Slope Error
EM
Dynamic Performance 10 kHz Sine Wave Input 1 dB below full scale, Max throughput, using AGND pin
Signal-to-Noise
Signal-to-Noise Plus Distortion
Total Harmonic Distortion (Up to
5th Harmonic)
Spurious-Free Dynamic Range
SNR
SNDR
THD
SFDR
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14 Bit Mode
664
72
—
dB
12 Bit Mode
64
68
—
dB
10 Bit Mode
59
61
—
dB
14 Bit Mode
664
72
—
dB
12 Bit Mode
64
68
—
dB
10 Bit Mode
59
61
—
dB
14 Bit Mode
—
-74
—
dB
12 Bit Mode
—
-72
—
dB
10 Bit Mode
—
-69
—
dB
14 Bit Mode
—
74
—
dB
12 Bit Mode
—
74
—
dB
10 Bit Mode
—
71
—
dB
Rev. 1.3 | 25
�EFM8LB1 Data Sheet
Electrical Specifications
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Note:
1. This time is equivalent to four periods of a clock running at 18 MHz + 2%.
2. Conversion Time does not include Tracking Time. Total Conversion Time is:
Total Conversion Time = RPT × (ADTK + NUMBITS + 1) × T(SARCLK) + (T(ADCCLK) × 4)
where RPT is the number of conversions represented by the ADRPT field and ADCCLK is the clock selected for the ADC.
3. Absolute input pin voltage is limited by the VIO supply.
4. Measured with characterization data and not production tested.
5. The offset is determined using curve fitting since the specification is measured using linear search where the intercept is always
positive.
6. Production test uses a 2.4 V external reference and external ground.
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Rev. 1.3 | 26
�EFM8LB1 Data Sheet
Electrical Specifications
4.1.10 Voltage Reference
Table 4.10. Voltage Reference
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
1.62
1.65
1.68
V
Internal Fast Settling Reference
Output Voltage
VREFFS
(Full Temperature and Supply
Range)
Temperature Coefficient
TCREFFS
—
50
—
ppm/°C
Turn-on Time
tREFFS
—
—
1.5
μs
Power Supply Rejection
PSRRREF
—
400
—
ppm/V
1.2 V Output
2.2
—
3.6
V
2.4 V Output
2.7
—
3.6
V
1.2 V Output, VDD = 3.3 V, T = 25
°C
1.195
1.2
1.205
V
1.2 V Output
1.18
1.2
1.22
V
2.4 V Output, VDD = 3.3 V, T = 25
°C
2.39
2.4
2.41
V
2.4 V Output
2.36
2.4
2.44
V
4.7 µF tantalum + 0.1 µF ceramic
bypass on VREF pin
—
3
—
ms
0.1 µF ceramic bypass on VREF
pin
—
100
—
µs
VREF = 2.4 V, Load = 0 to 200 µA
to GND
—
8
—
µV/µA
VREF = 1.2 V, Load = 0 to 200 µA
to GND
—
5
—
µV/µA
Load = 0 to 200 µA to GND
0.1
—
—
µF
FS
On-chip Precision Reference
Valid Supply Range
Output Voltage
Turn-on Time, settling to 0.5 LSB
Load Regulation
VDD
VREFP
tVREFP
LRVREFP
Load Capacitor
CVREFP
Short-circuit current
ISCVREFP
—
—
8
mA
Power Supply Rejection
PSRRVRE
—
75
—
dB
—
5
—
μA
FP
External Reference
Input Current
IEXTREF
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ADC Sample Rate = 1 Msps;
VREF = 3.0 V
Rev. 1.3 | 27
�EFM8LB1 Data Sheet
Electrical Specifications
4.1.11 Temperature Sensor
Table 4.11. Temperature Sensor
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Uncalibrated Offset
VOFF
TA = 0 °C
—
751
—
mV
Uncalibrated Offset Error1
EOFF
TA = 0 °C
—
19
—
mV
Slope
M
—
2.82
—
mV/°C
Slope Error1
EM
—
29
—
μV/°C
Linearity
LIN
T = 0 °C to 70 °C
—
-0.1 to
0.15
—
°C
T = -20 °C to 85 °C
—
-0.2 to
0.35
—
°C
T = -40 °C to 105 °C
—
-0.4 to 0.8
—
°C
—
3.5
—
μs
T = 0 °C to 70 °C
-2.6
—
1.8
°C
T = -20 °C to 85 °C
-2.9
—
2.7
°C
T = -40 °C to 105 °C
-3.2
—
4.2
°C
Turn-on Time
tON
Temp Sensor Error Using Typical
Slope and Factory-Calibrated Offset2, 3
ETOT
Note:
1. Represents one standard deviation from the mean.
2. The factory-calibrated offset value is stored in the read-only area of flash in locations 0xFFD4 (low byte) and 0xFFD5 (high byte).
The 14-bit result represents the output of the ADC when sampling the temp sensor using the 1.65 V internal voltage reference.
3. The temp sensor error includes the offset calibration error, slope error, and linearity error. The values are based upon characterization and are not tested across temperature in production. The values represent three standard deviations above and below the
mean. Additional information on achieving high measurement accuracy is available in AN929: Accurate Temperature Sensing
with the EFM8 Laser Bee MCU Family.
4.1.12 1.8 V Internal LDO Voltage Regulator
Table 4.12. 1.8V Internal LDO Voltage Regulator
Parameter
Output Voltage
Symbol
VOUT_1.8V
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Test Condition
Min
Typ
Max
Unit
1.79
1.84
1.88
V
Rev. 1.3 | 28
�EFM8LB1 Data Sheet
Electrical Specifications
4.1.13 DACs
Table 4.13. DACs
Parameter
Symbol
Output Voltage
Min
Typ
Max
Unit
VOUT
0
—
VDD
V
Output Current
IOUT
-2
—
2
mA
Resolution
Nbits
Throughput Rate
fS
Integral Nonlinearity
INL
Differential Nonlinearity
DNL
Output Noise
VNOISE
Test Condition
12
Bits
—
—
200
ksps
DAC0 and DAC2
-10
-1.77 /
1.56
10
LSB
DAC1 and DAC3
-11.5
-2.73 /
1.11
11.5
LSB
-1
—
1
LSB
—
110
—
μVRMS
—
±1
—
V/μs
—
2.6
5
μs
VREF = 2.4 V
fS = 0.1 Hz to 300 kHz
Slew Rate
SLEW
Output Settling Time to 1% Fullscale
tSETTLE
Power-on Time
tPWR
—
—
10
μs
Voltage Reference Range
VREF
1.15
—
VDD
V
Power Supply Rejection Ratio
PSRR
DC, VOUT = 50% Full Scale
—
78
—
dB
Total Harmonic Distortion
THD
VOUT = 10 kHz sine wave, 10% to
90%
54
—
—
dB
Offset Error
EOFF
VREF = 2.4 V
-8
0
8
LSB
Full-Scale Error
EFS
VREF = 2.4 V
-13
±5
13
LSB
External Load Impedance
RLOAD
2
—
—
kΩ
External Load Capacitance1
CLOAD
—
—
100
pF
—
100
1300
μV/mA
Load Regulation
VOUT change between 25% and
75% Full Scale
VOUT = 50% Full Scale
IOUT = -2 to 2 mA
Note:
1. No minimum external load capacitance is required. However, under low loading conditions, it is possible for the DAC output to
glitch during start-up. If smooth start-up is required, the minimum loading capacitance at the pin should be a minimum of 10 pF.
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Rev. 1.3 | 29
�EFM8LB1 Data Sheet
Electrical Specifications
4.1.14 Comparators
Table 4.14. Comparators
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Response Time, CPMD = 00
(Highest Speed)
tRESP0
+100 mV Differential
—
100
—
ns
-100 mV Differential
—
150
—
ns
Response Time, CPMD = 11 (Low- tRESP3
est Power)
+100 mV Differential
—
1.5
—
μs
-100 mV Differential
—
3.5
—
μs
Positive Hysteresis
CPHYP = 00
—
0.4
—
mV
CPHYP = 01
—
8
—
mV
CPHYP = 10
—
16
—
mV
CPHYP = 11
—
32
—
mV
CPHYN = 00
—
-0.4
—
mV
CPHYN = 01
—
-8
—
mV
CPHYN = 10
—
-16
—
mV
CPHYN = 11
—
-32
—
mV
CPHYP = 00
—
0.5
—
mV
CPHYP = 01
—
6
—
mV
CPHYP = 10
—
12
—
mV
CPHYP = 11
—
24
—
mV
CPHYN = 00
—
-0.5
—
mV
CPHYN = 01
—
-6
—
mV
CPHYN = 10
—
-12
—
mV
CPHYN = 11
—
-24
—
mV
CPHYP = 00
—
0.7
—
mV
CPHYP = 01
—
4.5
—
mV
CPHYP = 10
—
9
—
mV
CPHYP = 11
—
18
—
mV
CPHYN = 00
—
-0.6
—
mV
CPHYN = 01
—
-4.5
—
mV
CPHYN = 10
—
-9
—
mV
CPHYN = 11
—
-18
—
mV
CPHYP = 00
—
1.5
—
mV
CPHYP = 01
—
4
—
mV
CPHYP = 10
—
8
—
mV
CPHYP = 11
—
16
—
mV
HYSCP+
Mode 0 (CPMD = 00)
Negative Hysteresis
HYSCP-
Mode 0 (CPMD = 00)
Positive Hysteresis
HYSCP+
Mode 1 (CPMD = 01)
Negative Hysteresis
HYSCP-
Mode 1 (CPMD = 01)
Positive Hysteresis
HYSCP+
Mode 2 (CPMD = 10)
Negative Hysteresis
HYSCP-
Mode 2 (CPMD = 10)
Positive Hysteresis
HYSCP+
Mode 3 (CPMD = 11)
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Rev. 1.3 | 30
�EFM8LB1 Data Sheet
Electrical Specifications
Parameter
Symbol
Test Condition
Negative Hysteresis
HYSCP-
Mode 3 (CPMD = 11)
Min
Typ
Max
Unit
CPHYN = 00
—
-1.5
—
mV
CPHYN = 01
—
-4
—
mV
CPHYN = 10
—
-8
—
mV
CPHYN = 11
—
-16
—
mV
Input Range (CP+ or CP-)
VIN
-0.25
—
VIO+0.25
V
Input Pin Capacitance
CCP
—
7.5
—
pF
Internal Reference DAC Resolution Nbits
6
bits
Common-Mode Rejection Ratio
CMRRCP
—
70
—
dB
Power Supply Rejection Ratio
PSRRCP
—
72
—
dB
Input Offset Voltage
VOFF
-10
0
10
mV
Input Offset Tempco
TCOFF
—
3.5
—
μV/°
Min
Typ
Max
Unit
—
—
35.3
ns
—
3
—
ns
1 or 2 CLUs Cascaded
—
—
73.5
MHz
3 or 4 CLUs Cascaded
—
—
36.75
MHz
TA = 25 °C
4.1.15 Configurable Logic
Table 4.15. Configurable Logic
Parameter
Symbol
Test Condition
Propagation Delay
tDLY
Through single CLU
Using an external pin
Through single CLU
Using an internal connection
Clocking Frequency
FCLK
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�EFM8LB1 Data Sheet
Electrical Specifications
4.1.16 Port I/O
Table 4.16. Port I/O
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Output High Voltage (High Drive)
VOH
IOH = -7 mA, VIO ≥ 3.0 V
VIO - 0.7
—
—
V
IOH = -3.3 mA, 2.2 V ≤ VIO < 3.0 V
VIO x 0.8
—
—
V
IOL = 13.5 mA, VIO ≥ 3.0 V
—
—
0.6
V
IOL = 7 mA, 2.2 V ≤ VIO < 3.0 V
—
—
VIO x 0.2
V
IOH = -4.75 mA, VIO ≥ 3.0 V
VIO - 0.7
—
—
V
IOH = -2.25 mA, 2.2 V ≤ VIO < 3.0 V
VIO x 0.8
—
—
V
IOL = 6.5 mA, VIO ≥ 3.0 V
—
—
0.6
V
IOL = 3.5 mA, 2.2 V ≤ VIO < 3.0 V
—
—
VIO x 0.2
V
0.7 x
—
—
V
—
0.3 x
V
IOH = -1.8 mA, 1.71 V ≤ VIO < 2.2 V
Output Low Voltage (High Drive)
VOL
IOL = 3.6 mA, 1.71 V ≤ VIO < 2.2 V
Output High Voltage (Low Drive)
VOH
IOH = -1.2 mA, 1.71 V ≤ VIO < 2.2 V
Output Low Voltage (Low Drive)
VOL
IOL = 1.8 mA, 1.71 V ≤ VIO < 2.2 V
Input High Voltage
VIH
VIO
Input Low Voltage
VIL
—
VIO
Pin Capacitance
CIO
—
7
—
pF
Weak Pull-Up Current
IPU
VDD = 3.6
-30
-20
-10
μA
Input Leakage (Pullups off or Analog)
ILK
GND < VIN < VIO
-1.1
—
4
μA
Input Leakage Current with VIN
above VIO
ILK
VIO < VIN < VIO+2.5 V
0
5
150
μA
(VIN = 0 V)
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Rev. 1.3 | 32
�EFM8LB1 Data Sheet
Electrical Specifications
4.1.17 SMBus
Table 4.17. SMBus Peripheral Timing Performance (Master Mode)
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Standard Mode (100 kHz Class)
I2C Operating Frequency
fI2C
0
—
702
kHz
SMBus Operating Frequency
fSMB
401
—
702
kHz
Bus Free Time Between STOP and tBUF
START Conditions
9.4
—
—
µs
Hold Time After (Repeated)
START Condition
tHD:STA
4.7
—
—
µs
Repeated START Condition Setup
Time
tSU:STA
9.4
—
—
µs
STOP Condition Setup Time
tSU:STO
9.4
—
—
µs
Data Hold Time
tHD:DAT
2753
—
—
ns
Data Setup Time
tSU:DAT
3003
—
—
ns
Detect Clock Low Timeout
tTIMEOUT
25
—
—
ms
Clock Low Period
tLOW
4.7
—
—
µs
Clock High Period
tHIGH
9.4
—
504
µs
Fast Mode (400 kHz Class)
I2C Operating Frequency
fI2C
0
—
2562
kHz
SMBus Operating Frequency
fSMB
401
—
2562
kHz
Bus Free Time Between STOP and tBUF
START Conditions
2.6
—
—
µs
Hold Time After (Repeated)
START Condition
tHD:STA
1.3
—
—
µs
Repeated START Condition Setup
Time
tSU:STA
2.6
—
—
µs
STOP Condition Setup Time
tSU:STO
2.6
—
—
µs
Data Hold Time
tHD:DAT
2753
—
—
ns
Data Setup Time
tSU:DAT
3003
—
—
ns
Detect Clock Low Timeout
tTIMEOUT
25
—
—
ms
Clock Low Period
tLOW
1.3
—
—
µs
Clock High Period
tHIGH
2.6
—
504
µs
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�EFM8LB1 Data Sheet
Electrical Specifications
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Note:
1. The minimum SMBus frequency is limited by the maximum Clock High Period requirement of the SMBus specification.
2. The maximum I2C and SMBus frequencies are limited by the minimum Clock Low Period requirements of their respective specifications.
3. Data setup and hold timing at 40 MHz or lower with EXTHOLD set to 1. The DLYEXT bit can be used to adjust the data setup and
hold times.
4. SMBus has a maximum requirement of 50 µs for Clock High Period. Operating frequencies lower than 40 kHz will be longer than
50 µs. I2C can support periods longer than 50 µs.
Table 4.18. SMBus Peripheral Timing Formulas (Master Mode)
Parameter
Symbol
Clocks
SMBus Operating Frequency
fSMB
fCSO / 3
Bus Free Time Between STOP and START Conditions
tBUF
2 / fCSO
Hold Time After (Repeated) START Condition
tHD:STA
1 / fCSO
Repeated START Condition Setup Time
tSU:STA
2 / fCSO
STOP Condition Setup Time
tSU:STO
2 / fCSO
Clock Low Period
tLOW
1 / fCSO
Clock High Period
tHIGH
2 / fCSO
Note:
1. fCSO is the SMBus peripheral clock source overflow frequency.
tLOW
SCL
VIH
VIL
tHD:STA
SDA
tHD:DAT
tHIGH
tSU:DAT
tSU:STA
tSU:STO
VIH
VIL
tBUF
P
S
S
P
Figure 4.1. SMBus Peripheral Timing Diagram (Master Mode)
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�EFM8LB1 Data Sheet
Electrical Specifications
4.2 Thermal Conditions
Table 4.19. Thermal Conditions
Parameter
Symbol
Test Condition
Thermal Resistance (Junction to
Ambient)
θJA
Thermal Resistance (Junction to
Case)
θJC
Min
Typ
Max
Unit
QFN24 Packages
—
30
—
°C/W
QFN32 Packages
—
26
—
°C/W
QFP32 Packages
—
80
—
°C/W
QSOP24 Packages
—
65
—
°C/W
QFN24 Packages
—
32.8
—
°C/W
QFN32 Packages
—
20
—
°C/W
QFP32 Packages
—
24.3
—
°C/W
QSOP24 Packages
—
38.1
—
°C/W
Note:
1. Thermal resistance assumes a multi-layer PCB with any exposed pad soldered to a PCB pad.
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�EFM8LB1 Data Sheet
Electrical Specifications
4.3 Absolute Maximum Ratings
Stresses above those listed in Table 4.20 Absolute Maximum Ratings on page 36 may cause permanent damage to the device. This
is a stress rating only and functional operation of the devices at those or any other conditions above those indicated in the operation
listings of this specification is not implied. Exposure to maximum rating conditions for extended periods may affect device reliability. For
more information on the available quality and reliability data, see the Quality and Reliability Monitor Report at http://www.silabs.com/
support/quality/pages/default.aspx.
Table 4.20. Absolute Maximum Ratings
Parameter
Symbol
Ambient Temperature Under Bias
Min
Max
Unit
TBIAS
-55
125
°C
Storage Temperature
TSTG
-65
150
°C
Voltage on VDD
VDD
GND-0.3
4.2
V
Voltage on VIO2
VIO
GND-0.3
VDD+0.3
V
VIO > 3.3 V
GND-0.3
5.8
V
VIO < 3.3 V
GND-0.3
VIO+2.5
V
Voltage on I/O pins or RSTb, excluding VIN
P2.0-P2.3 (QFN24 and QSOP24) or
P3.0-P3.3 (QFN32 and QFP32)
Test Condition
Voltage on P2.0-P2.3 (QFN24 and
QSOP24) or P3.0-P3.3 (QFN32 and
QFP32)
VIN
GND-0.3
VDD+0.3
V
Total Current Sunk into Supply Pin
IVDD
—
400
mA
Total Current Sourced out of Ground
Pin
IGND
400
—
mA
Current Sourced or Sunk by any I/O
Pin or RSTb
IIO
-100
100
mA
Operating Junction Temperature
TJ
-40
130
°C
TA = -40 °C to 105 °C
Note:
1. Exposure to maximum rating conditions for extended periods may affect device reliability.
2. In certain package configurations, the VIO and VDD supplies are bonded to the same pin.
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�EFM8LB1 Data Sheet
Typical Connection Diagrams
5. Typical Connection Diagrams
5.1 Power
Figure 5.1 Power Connection Diagram on page 37 shows a typical connection diagram for the power pins of the device.
EFM8LB1 Device
2.2 - VDD V
2.2 - 3.6 V
4.7 µF and 0.1 µF bypass
capacitors required for
each power pin placed as
close to the pins as
possible.
VIO
VDD
GND
Figure 5.1. Power Connection Diagram
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�EFM8LB1 Data Sheet
Typical Connection Diagrams
5.2 Debug
The diagram below shows a typical connection diagram for the debug connections pins. The pin sharing resistors are only required if
the functionality on the C2D (a GPIO pin) and the C2CK (RSTb) is routed to external circuitry. For example, if the RSTb pin is connected to an external switch with debouncing filter or if the GPIO sharing with the C2D pin is connected to an external circuit, the pin sharing resistors and connections to the debug adapter must be placed on the hardware. Otherwise, these components and connections
can be omitted.
For more information on debug connections, see the example schematics and information available in AN124: Pin Sharing Techniques
for the C2 Interface. Application notes can be found on the Silicon Labs website (http://www.silabs.com/8bit-appnotes) or in Simplicity
Studio.
VDD
EFM8LB1 Device
C2CK
1k
1k
External
System
1k
(if pin sharing)
C2D
(if pin sharing)
1k
1k
GND
Debug Adapter
Figure 5.2. Debug Connection Diagram
5.3 Other Connections
Other components or connections may be required to meet the system-level requirements. Application Note AN203: "8-bit MCU Printed
Circuit Board Design Notes" contains detailed information on these connections. Application Notes can be accessed on the Silicon
Labs website (www.silabs.com/8bit-appnotes).
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Rev. 1.3 | 38
�EFM8LB1 Data Sheet
Pin Definitions
6. Pin Definitions
P0.1
P0.2
P0.3
P0.4
P0.5
P0.6
P0.7
P1.0
32
31
30
29
28
27
26
25
6.1 EFM8LB1x-QFN32 Pin Definitions
P0.0
1
24
P1.1
VIO
2
23
P1.2
VDD
3
22
P1.3
RSTb / C2CK
4
21
P1.4
P3.7 / C2D
5
20
P1.5
P3.4
6
19
P1.6
P3.3
7
18
P1.7
17
P2.0
32 pin QFN
(Top View)
GND
10
11
12
13
14
15
16
P2.6
P2.5
P2.4
P2.3
P2.2
P2.1
P3.1
P3.0
8
9
P3.2
Figure 6.1. EFM8LB1x-QFN32 Pinout
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Rev. 1.3 | 39
�EFM8LB1 Data Sheet
Pin Definitions
Table 6.1. Pin Definitions for EFM8LB1x-QFN32
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.0
Multifunction I/O
Yes
P0MAT.0
VREF
Number
1
INT0.0
INT1.0
CLU0A.8
CLU2A.8
CLU3B.8
2
VIO
I/O Supply Power Input
3
VDD
Supply Power Input
4
RSTb /
Active-low Reset /
C2CK
C2 Debug Clock
P3.7 /
Multifunction I/O /
C2D
C2 Debug Data
6
P3.4
Multifunction I/O
7
P3.3
Multifunction I/O
DAC3
8
P3.2
Multifunction I/O
DAC2
9
P3.1
Multifunction I/O
DAC1
10
P3.0
Multifunction I/O
DAC0
11
P2.6
Multifunction I/O
ADC0.19
5
CMP1P.8
CMP1N.8
12
P2.5
Multifunction I/O
CLU3OUT
ADC0.18
CMP1P.7
CMP1N.7
13
P2.4
Multifunction I/O
ADC0.17
CMP1P.6
CMP1N.6
14
P2.3
Multifunction I/O
Yes
P2MAT.3
ADC0.16
CLU1B.15
CMP1P.5
CLU2B.15
CMP1N.5
CLU3A.15
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P2.2
Multifunction I/O
Yes
P2MAT.2
ADC0.15
CLU2OUT
CMP1P.4
CLU1A.15
CMP1N.4
Number
15
CLU2B.14
CLU3A.14
16
P2.1
Multifunction I/O
Yes
P2MAT.1
ADC0.14
I2C0_SCL
CMP1P.3
CLU1B.14
CMP1N.3
CLU2A.15
CLU3B.15
17
P2.0
Multifunction I/O
Yes
P2MAT.0
CMP1P.2
I2C0_SDA
CMP1N.2
CLU1A.14
CLU2A.14
CLU3B.14
18
P1.7
Multifunction I/O
Yes
P1MAT.7
ADC0.13
CLU0B.15
CMP0P.9
CLU1B.13
CMP0N.9
CLU2A.13
19
P1.6
Multifunction I/O
Yes
P1MAT.6
ADC0.12
CLU0A.15
CLU1B.12
CLU2A.12
20
P1.5
Multifunction I/O
Yes
P1MAT.5
ADC0.11
CLU0B.14
CLU1A.13
CLU2B.13
21
P1.4
Multifunction I/O
Yes
P1MAT.4
ADC0.10
CLU0A.14
CLU1A.12
CLU2B.12
22
P1.3
Multifunction I/O
Yes
P1MAT.3
ADC0.9
CLU0B.13
CLU1B.11
CLU2B.11
CLU3A.13
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P1.2
Multifunction I/O
Yes
P1MAT.2
ADC0.8
CLU0A.13
CMP0P.8
CLU1A.11
CMP0N.8
Number
23
CLU2B.10
CLU3A.12
24
P1.1
Multifunction I/O
Yes
P1MAT.1
ADC0.7
CLU0B.12
CMP0P.7
CLU1B.10
CMP0N.7
CLU2A.11
CLU3B.13
25
P1.0
Multifunction I/O
Yes
P1MAT.0
ADC0.6
CLU1OUT
CMP0P.6
CLU0A.12
CMP0N.6
CLU1A.10
CMP1P.1
CLU2A.10
CMP1N.1
CLU3B.12
26
P0.7
Multifunction I/O
Yes
P0MAT.7
ADC0.5
INT0.7
CMP0P.5
INT1.7
CMP0N.5
CLU0B.11
CMP1P.0
CLU1B.9
CMP1N.0
CLU3A.11
27
P0.6
Multifunction I/O
Yes
P0MAT.6
ADC0.4
CNVSTR
CMP0P.4
INT0.6
CMP0N.4
INT1.6
CLU0A.11
CLU1B.8
CLU3A.10
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.5
Multifunction I/O
Yes
P0MAT.5
ADC0.3
INT0.5
CMP0P.3
INT1.5
CMP0N.3
Number
28
UART0_RX
CLU0B.10
CLU1A.9
CLU3B.11
29
P0.4
Multifunction I/O
Yes
P0MAT.4
ADC0.2
INT0.4
CMP0P.2
INT1.4
CMP0N.2
UART0_TX
CLU0A.10
CLU1A.8
CLU3B.10
30
P0.3
Multifunction I/O
Yes
P0MAT.3
EXTOSC
EXTCLK
INT0.3
INT1.3
CLU0B.9
CLU2B.9
CLU3A.9
31
P0.2
Multifunction I/O
Yes
P0MAT.2
ADC0.1
INT0.2
CMP0P.1
INT1.2
CMP0N.1
CLU0OUT
CLU0A.9
CLU2B.8
CLU3A.8
32
P0.1
Multifunction I/O
Yes
P0MAT.1
ADC0.0
INT0.1
CMP0P.0
INT1.1
CMP0N.0
CLU0B.8
AGND
CLU2A.9
CLU3B.9
Center
GND
Ground
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�EFM8LB1 Data Sheet
Pin Definitions
25
P0.6
P0.7
P1.0
27
26
P0.3
P0.4
P0.5
30
28
P0.2
31
29
P0.1
32
6.2 EFM8LB1x-QFP32 Pin Definitions
P0.0
GND
1
24
2
23
P1.1
P1.2
VIO
3
22
P1.3
VDD
4
21
P1.4
RSTb / C2CK
5
20
P1.5
P3.7 / C2D
6
19
P1.6
P3.3
7
18
P1.7
P3.2
8
17
P2.0
16
15
14
P2.3
P2.2
P2.1
P2.6
P2.5
P2.4
13
11
12
10
P3.0
P3.1
9
32 Pin QFP
Figure 6.2. EFM8LB1x-QFP32 Pinout
Table 6.2. Pin Definitions for EFM8LB1x-QFP32
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.0
Multifunction I/O
Yes
P0MAT.0
VREF
Number
1
INT0.0
INT1.0
CLU0A.8
CLU2A.8
CLU3B.8
2
GND
Ground
3
VIO
I/O Supply Power Input
4
VDD
Supply Power Input
5
RSTb /
Active-low Reset /
C2CK
C2 Debug Clock
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Rev. 1.3 | 44
�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
P3.7 /
Multifunction I/O /
C2D
C2 Debug Data
7
P3.3
Multifunction I/O
DAC3
8
P3.2
Multifunction I/O
DAC2
9
P3.1
Multifunction I/O
DAC1
10
P3.0
Multifunction I/O
DAC0
11
P2.6
Multifunction I/O
ADC0.19
Number
6
Additional Digital
Functions
Analog Functions
CMP1P.8
CMP1N.8
12
P2.5
Multifunction I/O
CLU3OUT
ADC0.18
CMP1P.7
CMP1N.7
13
P2.4
Multifunction I/O
ADC0.17
CMP1P.6
CMP1N.6
14
P2.3
Multifunction I/O
Yes
P2MAT.3
ADC0.16
CLU1B.15
CMP1P.5
CLU2B.15
CMP1N.5
CLU3A.15
15
P2.2
Multifunction I/O
Yes
P2MAT.2
ADC0.15
CLU2OUT
CMP1P.4
CLU1A.15
CMP1N.4
CLU2B.14
CLU3A.14
16
P2.1
Multifunction I/O
Yes
P2MAT.1
ADC0.14
I2C0_SCL
CMP1P.3
CLU1B.14
CMP1N.3
CLU2A.15
CLU3B.15
17
P2.0
Multifunction I/O
Yes
P2MAT.0
CMP1P.2
I2C0_SDA
CMP1N.2
CLU1A.14
CLU2A.14
CLU3B.14
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P1.7
Multifunction I/O
Yes
P1MAT.7
ADC0.13
CLU0B.15
CMP0P.9
CLU1B.13
CMP0N.9
Number
18
CLU2A.13
19
P1.6
Multifunction I/O
Yes
P1MAT.6
ADC0.12
CLU0A.15
CLU1B.12
CLU2A.12
20
P1.5
Multifunction I/O
Yes
P1MAT.5
ADC0.11
CLU0B.14
CLU1A.13
CLU2B.13
21
P1.4
Multifunction I/O
Yes
P1MAT.4
ADC0.10
CLU0A.14
CLU1A.12
CLU2B.12
22
P1.3
Multifunction I/O
Yes
P1MAT.3
ADC0.9
CLU0B.13
CLU1B.11
CLU2B.11
CLU3A.13
23
P1.2
Multifunction I/O
Yes
P1MAT.2
ADC0.8
CLU0A.13
CMP0P.8
CLU1A.11
CMP0N.8
CLU2B.10
CLU3A.12
24
P1.1
Multifunction I/O
Yes
P1MAT.1
ADC0.7
CLU0B.12
CMP0P.7
CLU1B.10
CMP0N.7
CLU2A.11
CLU3B.13
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P1.0
Multifunction I/O
Yes
P1MAT.0
ADC0.6
CLU1OUT
CMP0P.6
CLU0A.12
CMP0N.6
CLU1A.10
CMP1P.1
CLU2A.10
CMP1N.1
Number
25
CLU3B.12
26
P0.7
Multifunction I/O
Yes
P0MAT.7
ADC0.5
INT0.7
CMP0P.5
INT1.7
CMP0N.5
CLU0B.11
CMP1P.0
CLU1B.9
CMP1N.0
CLU3A.11
27
P0.6
Multifunction I/O
Yes
P0MAT.6
ADC0.4
CNVSTR
CMP0P.4
INT0.6
CMP0N.4
INT1.6
CLU0A.11
CLU1B.8
CLU3A.10
28
P0.5
Multifunction I/O
Yes
P0MAT.5
ADC0.3
INT0.5
CMP0P.3
INT1.5
CMP0N.3
UART0_RX
CLU0B.10
CLU1A.9
CLU3B.11
29
P0.4
Multifunction I/O
Yes
P0MAT.4
ADC0.2
INT0.4
CMP0P.2
INT1.4
CMP0N.2
UART0_TX
CLU0A.10
CLU1A.8
CLU3B.10
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.3
Multifunction I/O
Yes
P0MAT.3
EXTOSC
Number
30
EXTCLK
INT0.3
INT1.3
CLU0B.9
CLU2B.9
CLU3A.9
31
P0.2
Multifunction I/O
Yes
P0MAT.2
ADC0.1
INT0.2
CMP0P.1
INT1.2
CMP0N.1
CLU0OUT
CLU0A.9
CLU2B.8
CLU3A.8
32
P0.1
Multifunction I/O
Yes
P0MAT.1
ADC0.0
INT0.1
CMP0P.0
INT1.1
CMP0N.0
CLU0B.8
AGND
CLU2A.9
CLU3B.9
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�EFM8LB1 Data Sheet
Pin Definitions
P0.5
P0.6
20
P1.0
GND
3
17
P1.1
VDD / VIO
4
16
P1.2
RSTb / C2CK
5
15
GND
P3.0 / C2D
6
GND
14
P1.3
P2.3
7
11
21
18
13
P1.4
P1.6
P0.4
2
10
22
P0.0
P2.0
P0.3
23
P0.7
9
19
P2.1
1
P0.2
P0.1
24
6.3 EFM8LB1x-QFN24 Pin Definitions
24 pin QFN
12
P1.5
P2.2
8
(Top View)
Figure 6.3. EFM8LB1x-QFN24 Pinout
Table 6.3. Pin Definitions for EFM8LB1x-QFN24
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.1
Multifunction I/O
Yes
P0MAT.1
ADC0.0
INT0.1
CMP0P.0
INT1.1
CMP0N.0
CLU0B.8
AGND
Number
1
CLU2A.9
CLU3B.9
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.0
Multifunction I/O
Yes
P0MAT.0
VREF
Number
2
INT0.0
INT1.0
CLU0A.8
CLU2A.8
CLU3B.8
3
GND
Ground
4
VDD / VIO
Supply Power Input
5
RSTb /
Active-low Reset /
C2CK
C2 Debug Clock
P3.0 /
Multifunction I/O /
C2D
C2 Debug Data
P2.3
Multifunction I/O
6
7
Yes
P2MAT.3
DAC3
CLU1B.15
CLU2B.15
CLU3A.15
8
P2.2
Multifunction I/O
Yes
P2MAT.2
DAC2
CLU1A.15
CLU2B.14
CLU3A.14
9
P2.1
Multifunction I/O
Yes
P2MAT.1
DAC1
CLU1B.14
CLU2A.15
CLU3B.15
10
P2.0
Multifunction I/O
Yes
P2MAT.0
DAC0
CLU1A.14
CLU2A.14
CLU3B.14
11
P1.6
Multifunction I/O
Yes
P1MAT.6
ADC0.11
CLU3OUT
CMP1P.5
CLU0A.15
CMP1N.5
CLU1B.12
CLU2A.12
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P1.5
Multifunction I/O
Yes
P1MAT.5
ADC0.10
CLU2OUT
CMP1P.4
CLU0B.14
CMP1N.4
Number
12
CLU1A.13
CLU2B.13
13
P1.4
Multifunction I/O
Yes
P1MAT.4
ADC0.9
I2C0_SCL
CMP1P.3
CLU0A.14
CMP1N.3
CLU1A.12
CLU2B.12
14
P1.3
Multifunction I/O
Yes
P1MAT.3
CMP1P.2
I2C0_SDA
CMP1N.2
CLU0B.13
CLU1B.11
CLU2B.11
CLU3A.13
15
GND
Ground
16
P1.2
Multifunction I/O
Yes
P1MAT.2
ADC0.8
CLU0A.13
CLU1A.11
CLU2B.10
CLU3A.12
17
P1.1
Multifunction I/O
Yes
P1MAT.1
ADC0.7
CLU0B.12
CLU1B.10
CLU2A.11
CLU3B.13
18
P1.0
Multifunction I/O
Yes
P1MAT.0
ADC0.6
CLU0A.12
CLU1A.10
CLU2A.10
CLU3B.12
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.7
Multifunction I/O
Yes
P0MAT.7
ADC0.5
INT0.7
CMP0P.5
INT1.7
CMP0N.5
CLU1OUT
CMP1P.1
CLU0B.11
CMP1N.1
Number
19
CLU1B.9
CLU3A.11
20
P0.6
Multifunction I/O
Yes
P0MAT.6
ADC0.4
CNVSTR
CMP0P.4
INT0.6
CMP0N.4
INT1.6
CMP1P.0
CLU0A.11
CMP1N.0
CLU1B.8
CLU3A.10
21
P0.5
Multifunction I/O
Yes
P0MAT.5
ADC0.3
INT0.5
CMP0P.3
INT1.5
CMP0N.3
UART0_RX
CLU0B.10
CLU1A.9
CLU3B.11
22
P0.4
Multifunction I/O
Yes
P0MAT.4
ADC0.2
INT0.4
CMP0P.2
INT1.4
CMP0N.2
UART0_TX
CLU0A.10
CLU1A.8
CLU3B.10
23
P0.3
Multifunction I/O
Yes
P0MAT.3
EXTOSC
EXTCLK
INT0.3
INT1.3
CLU0B.9
CLU2B.9
CLU3A.9
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.2
Multifunction I/O
Yes
P0MAT.2
ADC0.1
INT0.2
CMP0P.1
INT1.2
CMP0N.1
Number
24
CLU0OUT
CLU0A.9
CLU2B.8
CLU3A.8
Center
GND
Ground
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�EFM8LB1 Data Sheet
Pin Definitions
6.4 EFM8LB1x-QSOP24 Pin Definitions
P0.3
1
24
P0.4
P0.2
2
23
P0.5
P0.1
3
22
P0.6
P0.0
4
21
P0.7
GND
5
20
P1.0
VDD / VIO
6
19
P1.1
RSTb / C2CK
7
18
P1.2
P3.0 / C2D
8
17
P1.3
P2.3
9
16
P1.4
P2.2
10
15
P1.5
P2.1
11
14
P1.6
P2.0
12
13
P1.7
24 pin QSOP
(Top View)
Figure 6.4. EFM8LB1x-QSOP24 Pinout
Table 6.4. Pin Definitions for EFM8LB1x-QSOP24
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.3
Multifunction I/O
Yes
P0MAT.3
EXTOSC
Number
1
EXTCLK
INT0.3
INT1.3
CLU0B.9
CLU2B.9
CLU3A.9
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.2
Multifunction I/O
Yes
P0MAT.2
ADC0.1
INT0.2
CMP0P.1
INT1.2
CMP0N.1
Number
2
CLU0OUT
CLU0A.9
CLU2B.8
CLU3A.8
3
P0.1
Multifunction I/O
Yes
P0MAT.1
ADC0.0
INT0.1
CMP0P.0
INT1.1
CMP0N.0
CLU0B.8
AGND
CLU2A.9
CLU3B.9
4
P0.0
Multifunction I/O
Yes
P0MAT.0
VREF
INT0.0
INT1.0
CLU0A.8
CLU2A.8
CLU3B.8
5
GND
Ground
6
VDD / VIO
Supply Power Input
7
RSTb /
Active-low Reset /
C2CK
C2 Debug Clock
P3.0 /
Multifunction I/O /
C2D
C2 Debug Data
P2.3
Multifunction I/O
8
9
Yes
P2MAT.3
DAC3
CLU1B.15
CLU2B.15
CLU3A.15
10
P2.2
Multifunction I/O
Yes
P2MAT.2
DAC2
CLU1A.15
CLU2B.14
CLU3A.14
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P2.1
Multifunction I/O
Yes
P2MAT.1
DAC1
Number
11
CLU1B.14
CLU2A.15
CLU3B.15
12
P2.0
Multifunction I/O
Yes
P2MAT.0
DAC0
CLU1A.14
CLU2A.14
CLU3B.14
13
P1.7
Multifunction I/O
Yes
P1MAT.7
ADC0.12
CLU0B.15
CMP1P.6
CLU1B.13
CMP1N.6
CLU2A.13
14
P1.6
Multifunction I/O
Yes
P1MAT.6
ADC0.11
CLU3OUT
CMP1P.5
CLU0A.15
CMP1N.5
CLU1B.12
CLU2A.12
15
P1.5
Multifunction I/O
Yes
P1MAT.5
ADC0.10
CLU2OUT
CMP1P.4
CLU0B.14
CMP1N.4
CLU1A.13
CLU2B.13
16
P1.4
Multifunction I/O
Yes
P1MAT.4
ADC0.9
I2C0_SCL
CMP1P.3
CLU0A.14
CMP1N.3
CLU1A.12
CLU2B.12
17
P1.3
Multifunction I/O
Yes
P1MAT.3
CMP1P.2
I2C0_SDA
CMP1N.2
CLU0B.13
CLU1B.11
CLU2B.11
CLU3A.13
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P1.2
Multifunction I/O
Yes
P1MAT.2
ADC0.8
Number
18
CLU0A.13
CLU1A.11
CLU2B.10
CLU3A.12
19
P1.1
Multifunction I/O
Yes
P1MAT.1
ADC0.7
CLU0B.12
CLU1B.10
CLU2A.11
CLU3B.13
20
P1.0
Multifunction I/O
Yes
P1MAT.0
ADC0.6
CLU0A.12
CLU1A.10
CLU2A.10
CLU3B.12
21
P0.7
Multifunction I/O
Yes
P0MAT.7
ADC0.5
INT0.7
CMP0P.5
INT1.7
CMP0N.5
CLU1OUT
CMP1P.1
CLU0B.11
CMP1N.1
CLU1B.9
CLU3A.11
22
P0.6
Multifunction I/O
Yes
P0MAT.6
ADC0.4
CNVSTR
CMP0P.4
INT0.6
CMP0N.4
INT1.6
CMP1P.0
CLU0A.11
CMP1N.0
CLU1B.8
CLU3A.10
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�EFM8LB1 Data Sheet
Pin Definitions
Pin
Pin Name
Description
Crossbar Capability
Additional Digital
Functions
Analog Functions
P0.5
Multifunction I/O
Yes
P0MAT.5
ADC0.3
INT0.5
CMP0P.3
INT1.5
CMP0N.3
Number
23
UART0_RX
CLU0B.10
CLU1A.9
CLU3B.11
24
P0.4
Multifunction I/O
Yes
P0MAT.4
ADC0.2
INT0.4
CMP0P.2
INT1.4
CMP0N.2
UART0_TX
CLU0A.10
CLU1A.8
CLU3B.10
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Rev. 1.3 | 58
�EFM8LB1 Data Sheet
QFN32 Package Specifications
7. QFN32 Package Specifications
7.1 Package Dimensions
Figure 7.1. Package Drawing
Table 7.1. Package Dimensions
Dimension
Min
Typ
Max
A
0.45
0.50
0.55
A1
0.00
0.035
0.05
b
0.15
0.20
0.25
D
D2
4.00 BSC.
2.80
2.90
e
0.40 BSC.
E
4.00 BSC.
3.00
E2
2.80
2.90
3.00
L
0.20
0.30
0.40
aaa
—
—
0.10
bbb
—
—
0.10
ccc
—
—
0.08
ddd
—
—
0.10
eee
—
—
0.10
ggg
—
—
0.05
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Rev. 1.3 | 59
�EFM8LB1 Data Sheet
QFN32 Package Specifications
Dimension
Min
Typ
Max
Note:
1. All dimensions shown are in millimeters (mm) unless otherwise noted.
2. Dimensioning and Tolerancing per ANSI Y14.5M-1994.
3. This drawing conforms to JEDEC Solid State Outline MO-220.
4. Recommended card reflow profile is per the JEDEC/IPC J-STD-020C specification for Small Body Components.
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�EFM8LB1 Data Sheet
QFN32 Package Specifications
7.2 PCB Land Pattern
Figure 7.2. PCB Land Pattern Drawing
Table 7.2. PCB Land Pattern Dimensions
Dimension
Min
Max
C1
—
4.10
C2
—
4.10
X1
—
0.2
X2
—
3.0
Y1
—
0.7
Y2
—
3.0
e
—
0.4
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Rev. 1.3 | 61
�EFM8LB1 Data Sheet
QFN32 Package Specifications
Dimension
Min
Max
Note:
1. All dimensions shown are in millimeters (mm) unless otherwise noted.
2. Dimensioning and Tolerancing is per the ANSI Y14.5M-1994 specification.
3. This Land Pattern Design is based on the IPC-7351 guidelines.
4. All dimensions shown are at Maximum Material Condition (MMC). Least Material Condition (LMC) is calculated based on a Fabrication Allowance of 0.05mm.
5. All metal pads are to be non-solder mask defined (NSMD). Clearance between the solder mask and the metal pad is to be 60 µm
minimum, all the way around the pad.
6. A stainless steel, laser-cut and electro-polished stencil with trapezoidal walls should be used to assure good solder paste release.
7. The stencil thickness should be 0.125 mm (5 mils).
8. The ratio of stencil aperture to land pad size should be 1:1 for all perimeter pads.
9. A 2 x 2 array of 1.10 mm square openings on a 1.30 mm pitch should be used for the center pad.
10. A No-Clean, Type-3 solder paste is recommended.
11. The recommended card reflow profile is per the JEDEC/IPC J-STD-020 specification for Small Body Components.
7.3 Package Marking
EFM8
PPPPPPPP
YYWW
TTTTTT #
Figure 7.3. Package Marking
The package marking consists of:
• PPPPPPPP – The part number designation.
• TTTTTT – A trace or manufacturing code.
• YY – The last 2 digits of the assembly year.
• WW – The 2-digit workweek when the device was assembled.
• # – The device revision (A, B, etc.).
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�EFM8LB1 Data Sheet
QFP32 Package Specifications
8. QFP32 Package Specifications
8.1 Package Dimensions
Figure 8.1. Package Drawing
Table 8.1. Package Dimensions
Dimension
Min
Typ
Max
A
—
—
1.20
A1
0.05
—
0.15
A2
0.95
1.00
1.05
b
0.30
0.37
0.45
c
0.09
—
0.20
D
9.00 BSC
D1
7.00 BSC
e
0.80 BSC
E
9.00 BSC
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Rev. 1.3 | 63
�EFM8LB1 Data Sheet
QFP32 Package Specifications
Dimension
Min
E1
L
Typ
7.00 BSC
0.50
0.60
aaa
0.20
bbb
0.20
ccc
0.10
ddd
0.20
theta
Max
0°
3.5°
0.70
7°
Note:
1. All dimensions shown are in millimeters (mm) unless otherwise noted.
2. Dimensioning and Tolerancing per ANSI Y14.5M-1994.
3. This drawing conforms to JEDEC outline MS-026.
4. Recommended card reflow profile is per the JEDEC/IPC J-STD-020 specification for Small Body Components.
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�EFM8LB1 Data Sheet
QFP32 Package Specifications
8.2 PCB Land Pattern
Figure 8.2. PCB Land Pattern Drawing
Table 8.2. PCB Land Pattern Dimensions
Dimension
Min
Max
C1
8.40
8.50
C2
8.40
8.50
E
0.80 BSC
X1
0.55
Y1
1.5
Note:
1. All dimensions shown are in millimeters (mm) unless otherwise noted.
2. This Land Pattern Design is based on the IPC-7351 guidelines.
3. All metal pads are to be non-solder mask defined (NSMD). Clearance between the solder mask and the metal pad is to be 60 µm
minimum, all the way around the pad.
4. A stainless steel, laser-cut and electro-polished stencil with trapezoidal walls should be used to assure good solder paste release.
5. The stencil thickness should be 0.125 mm (5 mils).
6. The ratio of stencil aperture to land pad size should be 1:1 for all perimeter pads.
7. A No-Clean, Type-3 solder paste is recommended.
8. The recommended card reflow profile is per the JEDEC/IPC J-STD-020C specification for Small Body Components.
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Rev. 1.3 | 65
�EFM8LB1 Data Sheet
QFP32 Package Specifications
8.3 Package Marking
EFM8
PPPPPPPPPPP
YYWWTTTTTT#
e3
Figure 8.3. Package Marking
The package marking consists of:
• PPPPPPPP – The part number designation.
• TTTTTT – A trace or manufacturing code.
• YY – The last 2 digits of the assembly year.
• WW – The 2-digit workweek when the device was assembled.
• # – The device revision (A, B, etc.).
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�EFM8LB1 Data Sheet
QFN24 Package Specifications
9. QFN24 Package Specifications
9.1 Package Dimensions
Figure 9.1. Package Drawing
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Rev. 1.3 | 67
�EFM8LB1 Data Sheet
QFN24 Package Specifications
Table 9.1. Package Dimensions
Dimension
Min
Typ
Max
A
0.8
0.85
0.9
A1
0.00
—
0.05
A2
—
0.65
—
A3
0.203 REF
b
0.15
0.2
0.25
b1
0.25
0.3
0.35
D
3.00 BSC
E
3.00 BSC
e
0.40 BSC
e1
0.45 BSC
J
1.60
1.70
1.80
K
1.60
1.70
1.80
L
0.35
0.40
0.45
L1
0.25
0.30
0.35
aaa
—
0.10
—
bbb
—
0.10
—
ccc
—
0.08
—
ddd
—
0.1
—
eee
—
0.1
—
Note:
1. All dimensions shown are in millimeters (mm) unless otherwise noted.
2. Dimensioning and Tolerancing per ANSI Y14.5M-1994.
3. This drawing conforms to JEDEC Solid State Outline MO-248 but includes custom features which are toleranced per supplier
designation.
4. Recommended card reflow profile is per the JEDEC/IPC J-STD-020 specification for Small Body Components.
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Rev. 1.3 | 68
�EFM8LB1 Data Sheet
QFN24 Package Specifications
9.2 PCB Land Pattern
c
X1
Y3
Y1
f
e
Y2
C2
c
X2
C1
Figure 9.2. PCB Land Pattern Drawing
Table 9.2. PCB Land Pattern Dimensions
Dimension
Min
Max
C1
3.00
C2
3.00
e
0.4 REF
X1
0.20
X2
1.80
Y1
0.80
Y2
1.80
Y3
0.4
f
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2.50 REF
Rev. 1.3 | 69
�EFM8LB1 Data Sheet
QFN24 Package Specifications
Dimension
Min
Max
c
0.25
0.35
Note:
1. All dimensions shown are in millimeters (mm) unless otherwise noted.
2. Dimensioning and Tolerancing is per the ANSI Y14.5M-1994 specification.
3. This Land Pattern Design is based on the IPC-SM-782 guidelines.
4. All metal pads are to be non-solder mask defined (NSMD). Clearance between the solder mask and the metal pad is to be 60 µm
minimum, all the way around the pad.
5. A stainless steel, laser-cut and electro-polished stencil with trapezoidal walls should be used to assure good solder paste release.
6. The stencil thickness should be 0.125 mm (5 mils).
7. The ratio of stencil aperture to land pad size should be 1:1 for all perimeter pads.
8. A 2 x 1 array of 0.7 mm x 1.6 mm openings on a 0.9 mm pitch should be used for the center pad.
9. A No-Clean, Type-3 solder paste is recommended.
10. The recommended card reflow profile is per the JEDEC/IPC J-STD-020 specification for Small Body Components.
9.3 Package Marking
PPPP
PPPPPP
TTTTTT
YYWW #
Figure 9.3. Package Marking
The package marking consists of:
• PPPPPPPP – The part number designation.
• TTTTTT – A trace or manufacturing code.
• YY – The last 2 digits of the assembly year.
• WW – The 2-digit workweek when the device was assembled.
• # – The device revision (A, B, etc.).
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Rev. 1.3 | 70
�EFM8LB1 Data Sheet
QSOP24 Package Specifications
10. QSOP24 Package Specifications
10.1 Package Dimensions
Figure 10.1. Package Drawing
Table 10.1. Package Dimensions
Dimension
Min
Typ
Max
A
—
—
1.75
A1
0.10
—
0.25
b
0.20
—
0.30
c
0.10
—
0.25
D
8.65 BSC
E
6.00 BSC
E1
3.90 BSC
e
0.635 BSC
L
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0.40
—
1.27
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�EFM8LB1 Data Sheet
QSOP24 Package Specifications
Dimension
theta
Min
Typ
Max
0º
—
8º
aaa
0.20
bbb
0.18
ccc
0.10
ddd
0.10
Note:
1. All dimensions shown are in millimeters (mm) unless otherwise noted.
2. Dimensioning and Tolerancing per ANSI Y14.5M-1994.
3. This drawing conforms to JEDEC outline MO-137, variation AE.
4. Recommended card reflow profile is per the JEDEC/IPC J-STD-020 specification for Small Body Components.
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Rev. 1.3 | 72
�EFM8LB1 Data Sheet
QSOP24 Package Specifications
10.2 PCB Land Pattern
Figure 10.2. PCB Land Pattern Drawing
Table 10.2. PCB Land Pattern Dimensions
Dimension
Min
Max
C
5.20
5.30
E
0.635 BSC
X
0.30
0.40
Y
1.50
1.60
Note:
1. All dimensions shown are in millimeters (mm) unless otherwise noted.
2. This land pattern design is based on the IPC-7351 guidelines.
3. All metal pads are to be non-solder mask defined (NSMD). Clearance between the solder mask and the metal pad is to be 60 µm
minimum, all the way around the pad.
4. A stainless steel, laser-cut and electro-polished stencil with trapezoidal walls should be used to assure good solder paste release.
5. The stencil thickness should be 0.125 mm (5 mils).
6. The ratio of stencil aperture to land pad size should be 1:1 for all perimeter pads.
7. A No-Clean, Type-3 solder paste is recommended.
8. The recommended card reflow profile is per the JEDEC/IPC J-STD-020 specification for Small Body Components.
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Rev. 1.3 | 73
�EFM8LB1 Data Sheet
QSOP24 Package Specifications
10.3 Package Marking
EFM8
PPPPPPPP #
TTTTTTYYWW
Figure 10.3. Package Marking
The package marking consists of:
• PPPPPPPP – The part number designation.
• TTTTTT – A trace or manufacturing code.
• YY – The last 2 digits of the assembly year.
• WW – The 2-digit workweek when the device was assembled.
• # – The device revision (A, B, etc.).
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�EFM8LB1 Data Sheet
Revision History
11. Revision History
Revision 1.3
December 2018
• Updated ordering part numbers to revision C.
• Updated 1. Feature List, Figure 3.1 Detailed EFM8LB1 Block Diagram on page 8, and 3.4 Clocking to removed external crystal oscillator as clock source.
• Updated 4.1.8 External Oscillator for RC oscillator specifications.
• Updated 3.10 Bootloader recommendations for production programming.
• Added more information about documentation to the 3.1 Introduction section.
• Removed all references to XTAL and renamed it to EXTOSC.
Revision 1.2
January 2018
• Added S1 devices. Updated 2. Ordering Information and 3.10 Bootloader with the new S1 device information.
• Updated 3.1 Introduction to mention all device documentation.
• Updated 4.1.1 Recommended Operating Conditions to remove the "GPIO levels are undefined whenever VIO is less than 1 V" note,
added a new minimum for VIO, and added a note referencing 4.1.16 Port I/O.
• Added a note to Table 4.2 Power Consumption on page 19 providing more information about the Comparator Reference specification.
• Renamed Thermal Resistance to Thermal Resistance (Junction to Ambient) and added Thermal Resistance (Junction to Case) to
4.2 Thermal Conditions.
• Updated the revision history format.
Revision 1.1
March 2017
•
•
•
•
•
•
Removed the note that AEC-Q100 qualification is pending from 1. Feature List and 2. Ordering Information.
Added 4.1.12 1.8 V Internal LDO Voltage Regulator.
Added a note to 4.1.9 ADC specifying the production test VREF and ground setup.
Added Output Voltage and Output Current specifications to 4.1.13 DACs.
Fixed the Symbol and Test Condition values for Output Noise in 4.1.13 DACs.
Updated the minimum VIO displayed in Figure 5.1 Power Connection Diagram on page 37 to match the specification in 4.1.1 Recommended Operating Conditions.
• Added a note to 3.1 Introduction referencing the Reference Manual.
• Corrected the application note number for AN124: Pin Sharing Techniques for the C2 Interface in 5.2 Debug.
• Adjusted the Data Hold and Data Setup Times in 4.1.17 SMBus and added a note referring to the DLYEXT bit.
Revision 1.01
October 2016
• Updated QFN24 center pad stencil description.
Revision 1.0
September 2016
•
•
•
•
•
•
Updated part numbers to revision B.
Updated many specifications with full characterization data.
Added a note regarding which DACs are available to Table 2.1 Product Selection Guide on page 3.
Added specifications for 4.1.17 SMBus.
Added bootloader pinout information to 3.10 Bootloader.
Added CRC Calculation Time to 4.1.4 Flash Memory.
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Rev. 1.3 | 75
�EFM8LB1 Data Sheet
Revision History
Revision 0.5
February 2016
• Updated Figure 5.2 Debug Connection Diagram on page 38 to move the pull-up resistor on C2D / RSTb to after the series resistor
instead of before.
• Added S0 devices and information about the SMBus bootloader in 3.10 Bootloader.
• Added a reference to AN945: EFM8 Factory Bootloader User Guide in 3.10 Bootloader.
• Added mention of the pre-programmed bootloaders in 1. Feature List.
• Updated all part numbers to revision B.
• Added the C oscillator, which is now available on revision B.
• Adjusted C1, C2, X2, Y2, and Y1 maximums for 7.2 PCB Land Pattern.
• Adjusted package markings for QFN32 and QSOP24 packages.
• Filled in TBD minimum and maximum values for DAC Differential Nonlinearity in Table 4.13 DACs on page 29.
Revision 0.4
•
•
•
•
Updated specification tables based on current device characterization status and production test limits.
Added bootloader section.
Added typical connection diagrams.
Corrected CLU connections in pin function tables.
Revision 0.3
• Added information on the bootloader to 3.10 Bootloader.
• Updated some characterization TBD values.
Revision 0.1
• Initial release.
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Rev. 1.3 | 76
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