LimeMicro:LMS6002D Datasheet: Difference between revisions

Serial Port Interface

Description

The functionality of the LMS6002 transceiver is fully controlled by a set of internal registers which can be accessed through a serial port interface. Both write and read operations are supported. The serial port can be configured to run in 3 or 4 wire mode with the following pins used:

• SEN - serial port enable, active low
• SCLK - serial clock
• SDIO - serial data in/out in 3 wire mode, serial data input in 4 wire mode
• SDO-serial data out in 4 wire mode, don’t care in 3 wire mode

Serial port key features:

• 16 serial clock cycles are required to complete write operation
• 16 serial clock cycles are required to complete read operation
• Multiple write/read operations are possible without toggling serial enable signal

All configuration registers are 8-bit wide. Write/read sequence consists of 8-bit instruction followed by 8-bit data to write or read. The MSB of the instruction bit stream is used as SPI command, where CMD = 1 for write and CMD = 0 for read. Next 3 bits represent the block address, since LMS6002 configuration registers are divided into eight logical blocks as shown in the LMS6002Dr2 Memory Map. The remaining 4 bits of the instruction are used to address particular registers within the block as detailed in the Memory Map Description. Use address values from the tables.

Write/read cycle waveforms are shown below. Note that write operation is the same for both 3-wire and 4-wire modes. Although not shown in the figures, multiple byte write/read is possible by repeating instruction/data sequence while keeping SEN low.

Write Operation Waveform

Read Operation Waveform, 4-Wire (Default)

Read Operation Waveform, 3-Wire

Memory Map Description

Memory Map

Top Level Configuration (User Mode)

Top Level Configuration (Test Mode)

TX/RX PLL Configuration (User Mode)

• Shadow registered

TX/RX PLL Configuration (Test Mode)

TX LPF Modules Configuration (User Mode)

TX LPF Modules Configuration (Test Mode)

RX LPF, DAC/ADC Modules Configuration (User Mode)

RX LPF, DAC/ADC Modules Configuration (Test Mode)

TX RF Modules Configuration (User Mode)

TX RF Modules Configuration (Test Mode)

RX VGA2 Configuration (User Mode)

RX VGA2 Configuration (Test Mode)

RX FE Modules Configuration (User Mode)

RX FE Modules Configuration (Test Mode)

Control Block Diagrams

SPI Read/Write Pseudocode

//----------------------------------------------------------------------------
// Write command, SPI module address, register address
// Read data
//----------------------------------------------------------------------------
void SPI_Read(BYTE COMMAND)
{
	BYTE DATA;	//We will read data there
	
	//Write Command and Address (MSB First)
//First 1 bit (MSB)  = Command
//Next 3 bits  = SPI memory block address
//Next 4 (LSBs) bits = Register Address
	for(int i=7; i>=0; i--)
	{		
		if(i’th bit in COMMAND is ‘1’)
		{
			Set Data Output line to ‘1’;
		}
		else
		{
			Set Data Output line to ‘0’;
		};
		Apply Rising and Falling CLK signal edges to CLK line;
	};

	//Read Data (MSB First)
	//Note: At this point we have data MSB valid from the chip.
	for(int i=7; i>=0; i--)
	{
		if(there is ‘1’ at the Data Input Line)
		{
			Set i’th bit in DATA ‘1’;
		}
		else
		{
			Set i’th bit in DATA ‘0’;
};
		Apply Rising and Falling CLK signal edges to CLK line;
	};
};

//----------------------------------------------------------------------------
// Write data to the chip:
// First byte: Command, SPI module address, register address
// Second byte: Data
//----------------------------------------------------------------------------
void SPI_Write(BYTE COMMAND, BYTE DATA)
{
	//Write Command, Address
	for(int i=7; i>=0; i--)
	{		
		if(i’th bit in COMMAND is ‘1’)
		{
			Set Data Output line to ‘1’;
		}
		else
		{
			Set Data Output line to ‘0’;
		};
		Apply Rising and Falling CLK signal edges to CLK line;
	};

	//Write Data
	for(int i=7; i>=0; i--)
	{		
		if(i’th bit in DATA is ‘1’)
		{
			Set Data Output line to ‘1’;
		}
		else
		{
			Set Data Output line to ‘0’;
		};
		Apply Rising and Falling CLK signal edges to CLK line;
	};
};

Loopback and Bypass Modes

Envelop and Pick Detector Multiplexer

TX/RX PLL

The frequency setting for both TX and RX PLLs is the same as described here. TX PLL SPI registers are at x001xxxx and TX PLL registers are at x010xxxx.

To configure the PLL there are a number of variables which need to be set.

• Integer and fractional part of the divider.
• FRANGE value.
• VCO CAP, charge pump current (Icp) and charge pump offset current (Ioff).

This assumes the given loop filter value with a loop BW of 100kHz is used.

FREQSEL

To simplify the TX/RX PLL register setup the FRANGE and SELVCO register are combined to FREQSEL register. The frequency range and FREQSEL[5:0] value table is reproduced below.

For example, UMTS Band I centre frequency 2140MHz is in the range 1.86 to 2.285GHz, hence FREQSEL = 100100 (0x24).

Integer and Fractional Part of the Divider

For wanted LO frequency ${\displaystyle {\mathit {f_{LO}}}}$ and given PLL reference clock frequency ${\displaystyle {\mathit {f_{REF}}}}$, calculate calculate integer and fractional part of the divider as below.

First, find temporary variable ${\displaystyle x}$ from the 3 least significant bits of the ${\displaystyle {\mathit {FREQSEL}}}$ value:

${\displaystyle x=2^{{\mathit {FREQSEL}}[2:0]-3}}$

Use x to calculate ${\displaystyle {\mathit {NINT}}}$ and ${\displaystyle {\mathit {NFRAC}}}$:

${\displaystyle {\mathit {NINT}}={\biggl \lfloor }{x*{\mathit {f_{LO}}} \over {\mathit {f_{REF}}}}{\biggr \rfloor }}$

${\displaystyle {\mathit {NFRAC}}={\biggl \lfloor }2^{23}{\biggl [}{x*{\mathit {f_{LO}}} \over {\mathit {f_{REF}}}}-{\mathit {NINT}}{\biggr ]}{\biggr \rfloor }}$

and store the values in ${\displaystyle {\mathit {NINT}}}$/${\displaystyle {\mathit {NFRAC}}}$ registers at address 0x10-0x13 for TXPLL and 0x20-0x23 for RX PLL.

For example ${\displaystyle {\mathit {f_{LO}}}}$ is band 1 centre frequency of 2140MHz, and ${\displaystyle {\mathit {f_{REF}}}}$ = 30.72MHz:

${\displaystyle {\mathit {FREQSEL}}[5:0]=0\mathrm {b} 100100,{\mathit {FREQSEL}}[2:0]=0\mathrm {b} 100=0\mathrm {x} 4=4}$

${\displaystyle x=2^{{\mathit {FREQSEL}}[2:0]-3}=2^{4-3}=2^{1}=2}$

${\displaystyle {\mathit {NINT}}={\biggl \lfloor }{x*{\mathit {f_{LO}}} \over {\mathit {f_{REF}}}}{\biggr \rfloor }={\biggl \lfloor }{2*2140 \over 30.72}{\biggr \rfloor }=139}$

${\displaystyle {\mathit {NFRAC}}={\biggl \lfloor }2^{23}{\biggl [}{x*{\mathit {f_{LO}}} \over {\mathit {f_{REF}}}}-{\mathit {NINT}}{\biggr ]}{\biggr \rfloor }={\biggl \lfloor }2^{23}{\biggl [}{2*2140 \over 30.72}-139{\biggr ]}{\biggr \rfloor }=2708821}$

VCO Capacitor, Icp and Ioff Selection

For the PLL loop filter implemented on the evaluation board, loop bandwidth of 100kHz and optimum PLL phase noise performance, the following charge pump current setup is recommended.

• Charge pump current Icp=1200uA (default).
• Charge pump current offset up Ioff up = 30uA.
• Charge pump current offset down Ioff down = 0uA (default).

Regarding VCOCAP selection, a flexible algorithm based on monitoring on chip Vtune comparators state is developed as described below.

Typical measured Vtune variation with the VCOCAP codes for the two target LO frequencies, 1.95GHz and 2.14GHz. Obviously, Vtune is changing from 2.9V down to 0V. However, PLL lock is guaranteed only when Vtune is in the range 0.5V-2.5V. Also, for the best phase noise performance, Vtune should be kept around the middle of the range i.e. 1.5V.

There are two on chip Vtune comparators per PLL as shown in PLL Control. Their threshold voltages are set to Vth Low=0.5V and Vth High=2.5V. The state of the comparators can be obtained by powering them up (register 0x1B for TXPLL or 0x2B for RXPLL, bit 3) and reading the register 0x1A for TXPPLL or 0x2A for RXPLL, bits 7-6. True table is given below.

These can be used to choose VCOCAP code. All we need to find is the code CMIN when comparators change the state from “10” to “00” and the code CMAX when the comparators change the state from “00” to “01”. Optimum VCOCAP code is then the middle one between CMIN and CMAX. For LO=2.4GHz, this is illustrated in VCO Capacitor, Icp and Ioff Selection. In this case, optimum code is around 41.

The algorithm is summarised as below.

1. Select correct FREQSEL.
2. Set target LO frequency (NINT, NFRAC) as explained in Integer and Fractional Part of the Divider
3. Sweep VCOCAP codes from 0-63. Monitor the state of Vtune comparators.
   1. Record the code CMIN when Vtune comparators state changes from "10" to "00" (PLL enters 'in range' state).
   2. Record the code CMAX when Vtune comparators state changes from "00" to "01" (PLL leaves 'in range' state).
   3. Select the middle code between CMIN and CMAX ( C=(CMIN+CMAX)/2 ).

Note that faster search algorithm (replacement for step 3 above) can be implemented as shown in VCO and VCOCAP Code Selection Algorithm.

Once the PLL is set, Vtune comparators can also be used as lock (in range) indication.

PLL Control

TX/RF LPF

TX RF

RXVGA2

RX FE

Calibration Flow Charts

General DC Calibration Procedure

DC Offset Calibration of LPF Tuning Module

TX/RX LPF DC Offset Calibration

RXVGA2 DC Offset Calibration

LPF Bandwidth Tuning

VCO and VCOCAP Code Selection Algorithm

General Procedure

VCO Selection

VCOCAP Selection

Auto Calibration Summary

The following is recommended auto calibration sequence.

1. DC offset cancellation of the LPF tuning module.
2. LPF bandwidth tuning.
3. DC offset cancellation of the TXLPF.
4. DC offset cancellation of the RXLPF.
5. DC offset cancellation of the RXVGA2.

Please note, while executing DC calibration procedures no TX/RX inputs should be applied.

LMS6002D has on-chip DACs for TX LO leakage calibration. Those DACs have been designed to provide around -50/-60dBc LO leakage cancellation.

Correction and Measurement Functions Implemented in BB

Applying IQ Gain Offset to Baseband Signals

Software in baseband initially applies course gain variation on the I or Q channel and measures the loopbacked signal via the LMS6002D receiver to measure the optimum value. The example block for gain correction is shown below.

This block implements the following equation:

${\displaystyle {\begin{aligned}{\mathit {Iout}}={\mathit {Iin}}*{\mathit {G\_I}}\\{\mathit {Qout}}={\mathit {Qin}}*{\mathit {G\_Q}}\end{aligned}}}$

${\displaystyle {\mathit {G\_I}}}$ and ${\displaystyle {\mathit {G\_Q}}}$ are programmable correction factors which are altered by the BB modem to minimise unwanted side band component.

Applying IQ Phase Band Offset Baseband Signals

The baseband S/W applies a course phase multiplier on the I or Q channel and measures the loopbacked signal via the LMS6002D receiver to measure the optimum value. The process is then repeated using a finer control step to ascertain the optimum phase and gain offset value to be applied. The example block for gain correction shown below.

IQ phase correction is in fact equivalent to vector rotation. If quadrature phase error is ${\displaystyle \alpha }$, then I and Q vectors are both rotated by ${\displaystyle \alpha /2}$ but in opposite directions hence IQ outputs of the corrector are 90° phase shifted. IQ phase correction equations are given below:

${\displaystyle {\begin{aligned}{\mathit {Iout}}={\mathit {Iin}}+{\mathit {Qin}}*\tan {\biggl (}{\alpha \over 2}{\biggr )}\\{\mathit {Qout}}={\mathit {Qin}}+{\mathit {Iin}}*\tan {\biggl (}{\alpha \over 2}{\biggr )}\end{aligned}}}$

The value of ${\displaystyle \tan(\alpha /2)}$ is used as a programmable correction parameter. BB modem should alter this value to minimise unwanted side band component.

Correcting RX I and Q DC Levels

Software in the receiver baseband is required to calibrate the DC level on the I and Q channel received. The process of applying DC level adjustment to the I & Q channel is an optional requirement required for fine tuning purposes only. The methodology of correcting the DC levels is shown in the diagram below.

The averaging (COMB) filter calculates the DC of the corrector input and that DC is subtracted to cancel it. The loop is running all the time so any change of the RX DC due to the signal level change, RX gain change or temperature will be tracked and cancelled automatically. The loop only programmable parameter is DCAVG which defines averaging window size.

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