LimeSDR-USB hardware description: Difference between revisions

LimeSDR-USB Board Key Features

The LimeSDR-USB development board provides a hardware platform for developing and prototyping high-performance and logic-intensive digital and RF designs using Altera’s Cyclone IV FPGA and Lime Microsystems transceiver.

The LimeSDR-USB has two different USB connector versions. LimeSDR-USB 1v4 is micro USB type B connector (socket) based, as shown in Figure 1. LimeSDR-USB 1v4s is a USB type A connector (plug) based, as shown in Figure 2.

LimeSDR-USB board features:

• USB Interface
  • Cypress FX3 Super Speed USB 3rd generation controller

• FPGA Features
  • Cyclone IV EP4CE40F23C8N device in 484-pin FPGA
  • 39’600 logic elements
  • 1134 Kbits embedded memory
  • 116 embedded 18x18 multipliers
  • 4 PLLs

• FPGA Configuration
  • JTAG mode configuration
  • Active serial mode configuration
  • Possibility to update FPGA gateware by using FX3 (USB)

• Memory Devices
  • 2x 1Gbit (64M x 16) DDR2 SDRAM
  • 4Mbit flash for FX3 firmware
  • 16Mbit flash for FPGA gateware
  • 2 x 128K (16K x 8) EEPROMs for LMS MCU firmware, LMS MCU data
  • 1 x 64K (8K x 8) EEPROM for FX3 data

• Connections
  • microUSB3.0 (type B) connector or USB3.0 (type A) plug
  • Coaxial RF (U.FL) connectors
  • FPGA GPIO headers (0.05” pitch)
  • FPGA and FX3 JTAG connectors (0.05” pitch)
  • 6..12V DC power jack and pinheader
  • Fan connector (3.3V)

• Clock System
  • 30.72MHz VCTCXO (precision: ±1 ppm initial, ±4 ppm stable).
  • Possibility to lock VCTCXO to external clock or tune VCTCXO by onboard DAC
  • Programmable clock generator for the FPGA reference clock input or LMS PLLs

• Board Size 60mm x 100mm (2.36” x 3.94”)

LimeSDR-USB board overview

LimeSDR-USB board version 1.4 picture with highlighted major connections presented in Figure 3. There are three connector types – data and debugging (USB3.0, FPGA GPIO and JTAG), power (DC jack and external supply pinheader) and high frequency (RF and reference clock).

Board components description listed in the Table 1 and Table 2.

Table 1. Board components

Featured Devices
Board reference	Type	Description
IC1	FPRF	Field programmable RF transceiver, LMS7002M
IC8	FPGA	Altera Cyclone IV, EP4CE40F23C8N 484-BGA
IC13	USB 3.0 microcontroller	Cypress FX3 Super Speed USB 3rd generation controller, CYUSB3014
Miscellaneous devices onboard
IC9	IC	Quad SPDT switch, TS3A5018PW
IC6	IC	Temperature sensor, LM75
IC19	IC	SPI to I²C bridge, SC18IS602BIPW (not mounted)
IC17	IC	I²C port expander with 4 push-pull outputs and 4 inputs, MAX7322ATE+
Configuration, Status and Setup Components
IC9	IC	Quad SPDT switch, TS3A5018PW
R51, R52, R53, R54, R56, R57, R59, R60	0 Ohm resistor	FPGA (IC31) MSEL[3:0]. Default mode: Active Serial Standard configuration
R115, R116, R117	10 kOhm resistor	USB3.0 microcontroller (IC13) boot configuration (PMODE0[2:0]) resistors. Default mode: SPI boot, On Failure - USB Boot
R125, R127, R128	10 kOhm resistor	USB3.0 microcontroller (IC13) crystal/clock frequency selection (FSLC[2:0]) resistors. Default mode: 19.2MHz crystal
J16	JTAG chain pin header	USB3.0 (IC6) microcontroller’s debugging pin header, 0.05” pitch
J17, R122	Pin header	USB3.0 microcontroller boot source (Flash memory or USB), 0.05” pitch jumper or 0402 0R resistor. In normal operation jumper or resistor must be placed.
SW1	Push-button	USB3.0 microcontroller reset button
J11	JTAG chain pin header	FPGA programming pin header for Altera USB-Blaster download cable, 0.05” pitch
LEDS1	Red-green status LEDs	User defined FPGA indication LED1 (near board edge if SMD; on the bottom if through-hole), User defined FPGA indication LED2 (farther board edge if SMD; on the top if through-hole)
LEDS2	Red-green status LEDs	FX3 (USB) status indication LED (near board edge if SMD; on the bottom if through-hole), board power indication LED (farther board edge if SMD; on the top if through-hole)
General User Input/Output
J12	Pin header	8 FPGA GPIOs, 0.05” pitch
J13, J14	Pin header	3.3V fan connection pin headers, 0.1” and 0.05” pitch respectively

Table 2. Board components

Memory Devices
Board reference	Type	Description
IC11, IC12	DDR2 memory	1Gbit (64M x 16) DDR2 SDRAM with a 16-bit data bus
IC2, IC3	EEPROM	128K (16K x 8) EEPROM, LMS7002 MCU firmware, LMS7002M data
IC18	EEPROM	64K (8K x 8) EEPROM, connected to main I2C bus
IC10	Flash memory	16Mbit Flash for FPGA configuration
IC15	Flash memory	4Mbit Flash for FX3 firmware
Communication Ports
J15	USB3.0 connector	microUSB3.0 (type B) connector or USB3.0 (type A) plug
Clock Circuitry
XO1, XO2	VCTCXO	30.72MHz voltage-controlled crystal oscillator
IC24	IC	Programmable clock generator for the FPGA reference clock input and RF boards
IC23	IC	ADF4002 phase detector
IC22	IC	DAC for TCXO (XT4) frequency tuning
J19	U.FL connector	Reference clock input
J18	U.FL connector	Reference clock output
Power Supply
J20	DC input jack	External 6V..12V DC power supply
J21	Pin header	External 6V..12V DC power supply and main internal power rail

LimeSDR-USB board version 1.4 picture with highlighted top components are presented in Figure 4.

LimeSDR-USB board version 1.4 picture with highlighted bottom components is presented in Figure 5.

LimeSDR-USB board architecture

The heart of the LimeSDR-USB board is Altera Cyclone IV FPGA. Its main function is to transfer digital data between the PC through a USB3.0 connector. The block diagram for LimeSDR-USB board is presented in the Figure 6.

LMS7002M based connectivity

The interface and control signals are described below:

• Digital Interface Signals: LMS7002 is using data bus LMS_DIQ1_D[11:0] and LMS_DIQ2_D[11:0], LMS_ENABLE_IQSEL1 and LMS_ENABLE_IQSEL2, LMS_FCLK1 and LMS_FCLK2, LMS_MCLK1 and LMS_MCLK2 signals to transfer data to/from FPGA. Indexes 1 and 2 indicate transceiver digital data PORT-1 or PORT-2. Any of these ports can be used to transmit or receive data. By default, PORT-1 is selected as transmit port and PORT-2 is selected as receiver port. The FCLK# is input clock and MCLK# is output clock for LMS7002M transceiver. TXNRX signals sets ports directions. For LMS7002M interface timing details refer to LMS7002M transceiver datasheet.

• LMS Control Signals: these signals are used for optional functionality:
  • LMS_RXEN, LMS_TXEN – receiver and transmitter enable/disable signals connected to FPGA Bank 8 (VDIO_LMS_FPGA; 2.5V).
  • LMS_RESET – LMS7002M reset connected to FPGA Bank 7 (VDIO_LMS_FPGA; 2.5V).

• SPI Interface: LMS7002M transceiver is configured via 4-wire SPI interface; FPGA_SPI0_SCLK, FPGA_SPI0_MOSI, FPGA_SPI0_MISO, FPGA_SPI0_LMS_SS. The SPI interface controlled from FPGA Bank 8 (VDIO_LMS_FPGA; 2.5V).

• Main I2C Interface: used to control external clock synthesizer, port expander, temperature sensor, EEPROM, I2C-SPI bridge on LimeSDR-USB board. The signals FX3_I2C_SCL, FX3_I2C_SDA connected to FX3. Also these I2C lines are connected via 0R resistors to FPGA Bank 8 (VCC3P3; 3.3V) lines FPGA_I2C_SCL, FPGA_I2C_SDA.

• LMS I2C Interface: can be used for LMS EEPROM content modifying or for debug purposes. The signals LMS_I2C_SCL, LMS_I2C_DATA connected to FPGA Bank 8 (VDIO_LMS_FPGA; 2.5V).

SDRAM

LimeSDR-USB board has two 128MB (16bit bus) DDR2 SDRAM ICs (AS4C64M16D2-25BCN) connected to double data rate pins on Cyclone IV 1.8V Bank 2, Bank 3 and Bank 4. RAM chips are connected to separate memory controllers so RAM chips works in dual channel mode. The memory can be used for data manipulation at high date rates between transceiver and FPGA.

USB 3.0 controller

Software controls LimeSDR-USB board via the USB3 microcontroller (CYUSB3014 (FX3)). The data transfer to/from the board, SPI communication, FPGA configuration is done via the USB3 controller. The controller signals description showed below:

• FX3_DQ[31:0] – FX3 32-bit GPIF data interface is connected to Cyclone IV 1.8V Bank 5.
• FX3_CTL[8:0], [12:11] – FX3 GPIF interface control signals.
• FX3_PCLK – GPIF interface clock. Clock from FX3 is fed to FPGA.
• FX3_SPI interface is used to program FX3 firmware flash or FPGA configuration flash memory.
• FX3 I2C bus is connected to the main I2C bus.
• PMODE[2:0] – boot options, by default boot from SPI and USB boot is enabled. If J17 jumper is present or R122 is soldered FX3 will boot from IC8 flash memory if correct firmware exists.
• SW1 – resets FX3
• J16 – FX3 JTAG programming/debugging pin header.

Indication LEDs

LimeSDR-USB board comes with four dual colour (red and green (RG)) indication LEDs. These LEDs can be SMD or 3mm TH with dedicated right angle plastic holders. By default, dual colour SMD LEDs are populated and through hole LEDs are unpopulated. If required, the user can fit dual colour TH LEDs.

Each LED has it is own function. Most of LEDs are connected to FPGA and their function can be changed. Default LEDs functions and other information are listed in the table below.

Table 3. Default functions of LEDs

Board reference	Schematic name	Board label	Type	Description
LED8, LEDS2.2	GND, VCC3P3	PWR	Power status	LED is hardwired to VCC3P3 power rail. Steady green light indicates presence of 3.3v.
LED2, LEDS2.1	FX3_LED_R, FX3_LED_G	FX3	USB activity	USB3.0 (FX3) controller, slave FIFO (GPIF) interface module and NIOS CPU activity indication: Green – idle, Red – busy.
LED1, LEDS1.1	FPGA_LED1_G, FPGA_LED1_R	FPGA1	Clock status	Blinking indicates presence of TCXO clock. Colour indicates status of FPGA PLLs that are used for LMS digital interface clocking: Green – both PLLs are locked; Red/Green – at least one PLL is not locked.
LED7, LEDS1.2	FPGA_LED2_G, FPGA_LED2_R	FPGA2	TCXO control mode	No light – TCXO is controlled from DAC Red – TCXO is controlled from phase detector and is not locked to external reference clock Green – TCXO is controlled from phase detector and is locked to external reference clock

Low speed interfaces

LimeSDR-USB board low speed interfaces are divided into FX3 and FPGA groups that are presented in Figure 3, Figure 8 and Figure 9. The latter block diagrams depict the main ICs, corresponding IC pin numbers, data buses and serial protocol addresses.

LimeSDR-USB board peripherals are controlled via USB interface. All commands that comes from USB are firstly processed by FX3 controller. If I2C peripheral (temperature sensor, port expander, clock generator) on FX3_I2C bus must be controlled this can be done directly. FX3_I2C is also connected to FPGA.

There are several SPI interfaces with their slave devices:

• FX3_SPI: FX3 hardware SPI cannot be used if 32-bit GPIF interface is configured. If any slave device on this bus must be accessed then FX3 switches to 16-bit GPIF. This bus has these slave devices:
  • FX3 firmware Flash
  • FPGA configuration flash: using switch (IC9) flash memory is switched from FPGA to FX3_SPI BUS. Then flash content is updated and flash memory is switch back to FPGA. This is done when needs to update FPGA gateware in flash memory.

• FPGA_SPI0, FPGA_SPI1: these SPI interfaces are connected to FPGA and slave devices can be accessed by transferring data to internal FPGA NIOS CPU. This bus has these slave devices:
  • RFIC (FPGA_SPI0)
  • Phase detector (FPGA_SPI1)
  • DAC (FPGA_SPI1)

• Internal FPGA SPI module: FPGA has its own SPI module and can be controlled as regular SPI device. By using FPGA SPI it is possible to control FPGA modes etc.

• BRDG_SPI: this is alternative SPI interface for FX3 and currently is not used.

In the table below are listed USB3.0 controller (FX3) pins, schematic signal name, FPGA interconnections and I/O standard.

Table 4. USB3 controller (FX3) pins

FX3	FX3 reference	Schematic signal name	FPGA pin	FPGA pin I/O standard	Comment
F10	GPIO0	FX3_DQ0	M19	1.8V
F9	GPIO1	FX3_DQ1	AA21	1.8V
F7	GPIO2	FX3_DQ2	Y22	1.8V
G10	GPIO3	FX3_DQ3	Y21	1.8V
G9	GPIO4	FX3_DQ4	W22	1.8V
F8	GPIO5	FX3_DQ5	W21	1.8V
H10	GPIO6	FX3_DQ6	W20	1.8V
H9	GPIO7	FX3_DQ7	V22	1.8V
J10	GPIO8	FX3_DQ8	V21	1.8V
J9	GPIO9	FX3_DQ9	U22	1.8V
K11	GPIO10	FX3_DQ10	U21	1.8V
L10	GPIO11	FX3_DQ11	U20	1.8V
K10	GPIO12	FX3_DQ12	U19	1.8V
K9	GPIO13	FX3_DQ13	M22	1.8V
J8	GPIO14	FX3_DQ14	M21	1.8V
G8	GPIO15	FX3_DQ15	R22	1.8V
J6	GPIO16	FX3_PCLK	T21	1.8V
K8	GPIO17	FX3_CTL0	L6	1.8V
K7	GPIO18	FX3_CTL1	L7	1.8V
J7	GPIO19	FX3_CTL2	M1	1.8V
H7	GPIO20	FX3_CTL3	M2	1.8V
G7	GPIO21	FX3_CTL4	M3	1.8V
G6	GPIO22	FX3_CTL5	M4	1.8V
K6	GPIO23	FX3_CTL6	M6	1.8V
H8	GPIO24	FX3_CTL7	M7	1.8V
G5	GPIO25	FX3_CTL8	M8	1.8V
H6	GPIO26	FX3_DCTL9	P9	1.8V
K5	GPIO27	FX3_DCTL10	N7	1.8V
J5	GPIO28	FX3_CTL11	N5	1.8V
H5	GPIO29	FX3_CTL12	N6	1.8V
G4	GPIO30	FX3_PMODE0	-	1.8V
H4	GPIO31	FX3_PMODE1	-	1.8V
L4	GPIO32	FX3_PMODE2	-	1.8V
K2	GPIO33	FX3_DQ16	R21	1.8V
J4	GPIO34	FX3_DQ17	R20	1.8V
K1	GPIO35	FX3_DQ18	R19	1.8V
J2	GPIO36	FX3_DQ19	R18	1.8V
J3	GPIO37	FX3_DQ20	P22	1.8V
J1	GPIO38	FX3_DQ21	P21	1.8V
H2	GPIO39	FX3_DQ22	M20	1.8V
H3	GPIO40	FX3_DQ23	P16	1.8V
F4	GPIO41	FX3_DQ24	P15	1.8V
G2	GPIO42	FX3_DQ25	N22	1.8V
G3	GPIO43	FX3_DQ26	N21	1.8V
F3	GPIO44	FX3_DQ27	N20	1.8V
F2	GPIO45	BRDG_INT_LS	-	1.8V	Connected to I2C-SPI bridge
F5	GPIO46	FX3_DQ28	N19	1.8V
E1	GPIO47	FX3_DQ29	N18	1.8V
E5	GPIO48	FX3_DQ30	N17	1.8V
E4	GPIO49	FX3_DQ31	N16	1.8V
D1	GPIO50	-	-	1.8V
D2	GPIO51	-	-	1.8V
D3	GPIO52	-	-	1.8V
D4	GPIO53	FX3_SPI_SCLK	-	3.3V
C1	GPIO54	FX3_SPI_FLASH_SS	-	3.3V
C2	GPIO55	FX3_SPI_MISO	-	3.3V
D5	GPIO56	FX3_SPI_MOSI	-	3.3V
C4	GPIO57	-	-	3.3V
D9	I2C_GPIO58	FX3_I2C_SCL/FPGA_I2C_SCL	H7	3.3V	Connected to I2C-SPI bridge
D10	I2C_GPIO59	FX3_I2C_SDA/FPGA_I2C_SDA	J7	3.3V	Connected to I2C-SPI bridge

In the table below are listed RF transceiver (LMS7002M) pins, schematic signal name, FPGA interconnections and I/O standard.

Table 5. RF transceiver (LMS7002M) digital interface pins

LMS7002M pin	LMS7002M reference	Schematic signal name	FPGA pin	FPGA pin I/O standard	Comment
AM24	xoscin_rx	RxPLL_CLK	-	3.3V	Connected to 30.72 MHz clock
P34	MCLK2	LMS_MCLK2	B11	2.5V
R29	FCLK2	LMS_FCLK2	E5	2.5V
U31	TXNRX2	LMS_TXNRX2	B8	2.5V
V34	RXEN	LMS_RXEN	C3	2.5V
R33	ENABLE_IQSEL2	LMS_ENABLE_IQSEL2	C7	2.5V
H30	DIQ2_D0	LMS_DIQ2_D0	B7	2.5V
J31	DIQ2_D1	LMS_DIQ2_D1	B6	2.5V
K30	DIQ2_D2	LMS_DIQ2_D2	B4	2.5V
K32	DIQ2_D3	LMS_DIQ2_D3	B3	2.5V
L31	DIQ2_D4	LMS_DIQ2_D4	A10	2.5V
K34	DIQ2_D5	LMS_DIQ2_D5	A9	2.5V
M30	DIQ2_D6	LMS_DIQ2_D6	A8	2.5V
M32	DIQ2_D7	LMS_DIQ2_D7	A7	2.5V
N31	DIQ2_D8	LMS_DIQ2_D8	A6	2.5V
N33	DIQ2_D9	LMS_DIQ2_D9	A5	2.5V
P30	DIQ2_D10	LMS_DIQ2_D10	A4	2.5V
P32	DIQ2_D11	LMS_DIQ2_D11	A11	2.5V
E5	xoscin_tx	TxPLL_CLK	-	3.3V	Connected to 30.72 MHz clock
AB34	MCLK1	LMS_MCLK1	G21	2.5V
AA33	FCLK1	LMS_FCLK1	B20	2.5V
V32	TXNRX1	LMS_TXNRX1	B9	2.5V
U29	TXEN	LMS_TXEN	B10	2.5V
Y32	ENABLE_IQSEL1	LMS_ENABLE_IQSEL1	C4	2.5V
AG31	DIQ1_D0	LMS_DIQ1_D0	B17	2.5V
AF30	DIQ1_D1	LMS_DIQ1_D1	B16	2.5V
AF34	DIQ1_D2	LMS_DIQ1_D2	B15	2.5V
AE31	DIQ1_D3	LMS_DIQ1_D3	B14	2.5V
AD30	DIQ1_D4	LMS_DIQ1_D4	B13	2.5V
AC29	DIQ1_D5	LMS_DIQ1_D5	C13	2.5V
AE33	DIQ1_D6	LMS_DIQ1_D6	A18	2.5V
AD32	DIQ1_D7	LMS_DIQ1_D7	A17	2.5V
AC31	DIQ1_D8	LMS_DIQ1_D8	A16	2.5V
AC33	DIQ1_D9	LMS_DIQ1_D9	A15	2.5V
AB30	DIQ1_D10	LMS_DIQ1_D10	A14	2.5V
AB32	DIQ1_D11	LMS_DIQ1_D11	A13	2.5V
U33	CORE_LDO_EN	LMS_CORE_LDO_EN	B18	2.5V
E27	RESET	LMS_RESET	C6	2.5V
D28	SEN	FPGA_SPI0_LMS_SS	D10	2.5V	SPI interface
C29	SCLK	FPGA_SPI0_SCLK	E6	2.5V	SPI interface
F30	SDIO	FPGA_SPI0_MOSI	D7	2.5V	SPI interface
F28	SDO	FPGA_SPI0_MISO	C8	2.5V	SPI interface
D26	SDA	LMS_I2C_SDA	C21	2.5V	Connected to EEPROM too
C27	SCL	LMS_I2C_SCL	C17	2.5V	Connected to EEPROM too

SPI interfaces, connected to the FPGA are listed in the tables bellow.

Table 6. FPGA_SPI0 interface pins

Schematic net name	FPGA pin	I/O standard	Comment
FPGA_SPI0_SCLK	E6	2.5V	Serial Clock (FPGA output)
FPGA_SPI0_MOSI	D7	2.5V	Data (FPGA output)
FPGA_SPI0_MISO	C8	2.5V	Data (FPGA input)
FPGA_SPI0_LMS_SS	D10	2.5V	IC1 (LMS7002M) SPI slave select

Table 7. FPGA_SPI1 interface pins

Schematic net name	FPGA pin	I/O standard	Comment
FPGA_SPI0_SCLK	E6	2.5V	Serial Clock (FPGA output)
FPGA_SPI0_MOSI	D7	2.5V	Data (FPGA output)
FPGA_SPI0_MISO	C8	2.5V	Data (FPGA input)
FPGA_SPI0_LMS_SS	D10	2.5V	IC1 (LMS7002M) SPI slave select

FX3 MCU features I2C interface. Slave devices and related information, connected to this interface, are listed in the table bellow.

Table 8. FX3 I2C interface pins

I2C slave device reference	I2C slave device	I2C slave address	I/O standard	Comment
IC9	Temperature sensor	1001000RW	3.3V	LM75
IC12	I2C SPI Bridge	0101000RW	3.3V	SC18IS602B
IC10	I2C Port Expander	1101101RW	3.3V	MAX7322
IC11	EEPROM	1010000RW	3.3V	24FC64F
IC17	Clock generator	1100000RW	3.3V	Si5351C

Eight GPIOs from FPGA are connected to 10 pin 0.05” header. Additional 2 pins are dedicated for power. FPGA_GPIO related information is presented in the table below.

Table 9. FPGA GPIO connector pins

Connector pin	Schematic net name	FPGA pin	I/O standard	Comment
1	FPGA_GPIO0	H8	3.3V
2	FPGA_GPIO1	H6	3.3V
3	FPGA_GPIO2	H2	3.3V
4	FPGA_GPIO3	H1	3.3V
5	FPGA_GPIO4	G4	3.3V
6	FPGA_GPIO5	G3	3.3V
7	FPGA_GPIO6	F2	3.3V
8	FPGA_GPIO7	F1	3.3V
9	GND	-	-
10	PWR	-	-	Selectable power net. Default 3.3V

Board temperature control

LimeSDR-USB has integrated temperature sensor which controls FAN to keep board in operating temperature range. FAN must be connected to J13 (0.1” pitch) connector or to J14 (0.05” pitch) connector. FAN control voltage is 3.3V.

Fan will be turned on if board will heat up to 55°C and FAN will be turned off if board will cool down to 45°C.

Measured temperature value can read by using LimeSuiteGUI.

Connect the fan as shown in the picture bellow.

Clock distribution

LimeSDR-USB board clock distribution block diagram is presented in Figure 12.

LimeSDR-USB board has onboard 30.72 MHz VCTCXO (precision: ±1 ppm initial, ±4 ppm stable) that is reference clock for LMS_PLLs. See block diagram of the clock distribution system in Figure 12.

VCTCXO can be tuned by onboard phase detector (IC23, ADF4002) or by DAC (IC22). The onboard frequency synthesizer is used to synchronize onboard VCTCXO with external equipment (via J19 U.FL connector) to calibrate frequency error. At the same time only ADF or DAC can control VCTCXO. Selection between ADF and DAC is done automatically. When board is powered, by default VCTCXO is controlled by DAC.

J19 connector can also be used to supply external reference clock (fitting R147, removing R137, C354).

The programmable clock generator (Si5351C) can generate any reference clock frequency, starting from 8 kHz – 160 MHz, for FPGA and LMS PLLs.

Table 10. LimeSDR-USB clock pins

Source	Schematic net name	FPGA pin	I/O standard	Comment
Programmable clock generator (IC24)	SI_CLK0	T2	1.8V
	SI_CLK1	AA12	1.8V
	SI_CLK2	AB12	1.8V
	SI_CLK3	T22	1.8V
	SI_CLK5	G1	3.3V
	SI_CLK6	AA11	1.8V
	SI_CLK7	AB11	1.8V
Clock buffer (IC13)	LMK_CLK	B12	3.3V	30.72MHz
RF transceiver (IC1)	LMS_MCLK1	G21	3.3V
	LMS_FCLK1	B20	3.3V
	LMS_MCLK2	B11	3.3V
	LMS_FCLK2	E5	3.3V
USB3.0 controller	FX3_PCLK	T21	1.8V
	FPGA_CLK_OUT	C2	3.3V

Power distribution

LimeSDR-USB board can be powered from USB port. In applications where USB power is insufficient board can be powered from external 6..12V power supply. External power supply can be fed to J20 barrel power connector by using power plug (1.35mm ID, 3.5mm OD) or pin header J21 (GND and VCC_EXT). External power supply connections have automatic source selection between USB and external source with polarity protection.

LimeSDR-USB board has complex power delivery network consisting of many different power rails with different voltages, filters, power sequences. LimeSDR-USB board power distribution block diagram is presented in Figure 13.

Power network power circuit ICs are presented in Figure 14.

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