AD9361 データシートの表示（PDF） - Analog Devices

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AD9361

RF Agile Transceiver

Analog Devices 

AD9361

SYNTHESIZERS

RF PLLs

The AD9361 contains two identical synthesizers to generate the

required LO signals for the RF signal paths:—one for the receiver

and one for the transmitter. Phase-locked loop (PLL) synthesizers

are fractional-N designs incorporating completely integrated

voltage controlled oscillators (VCOs) and loop filters. In TDD

operation, the synthesizers turn on and off as appropriate for the

RX and TX frames. In FDD mode, the TX PLL and the RX PLL

can be activated simultaneously. These PLLs require no external

components.

BB PLL

The AD9361 also contains a baseband PLL synthesizer that is

used to generate all baseband related clock signals. These include

the ADC and DAC sampling clocks, the DATA_CLK signal (see

the Digital Data Interface section), and all data framing signals.

This PLL is programmed from 700 MHz to 1400 MHz based on

the data rate and sample rate requirements of the system.

DIGITAL DATA INTERFACE

The AD9361 data interface uses parallel data ports (P0 and P1)

to transfer data between the device and the BBP. The data ports can

be configured in either single-ended CMOS format or differential

LVDS format. Both formats can be configured in multiple

arrangements to match system requirements for data ordering and

data port connections. These arrangements include single port

data bus, dual port data bus, single data rate, double data rate,

and various combinations of data ordering to transmit data

from different channels across the bus at appropriate times.

Bus transfers are controlled using simple hardware handshake

signaling. The two ports can be operated in either bidirectional

(TDD) mode or in full duplex (FDD) mode where half the bits

are used for transmitting data and half are used for receiving data.

The interface can also be configured to use only one of the data

ports for applications that do not require high data rates and

prefer to use fewer interface pins.

DATA_CLK Signal

RX data supplies the DATA_CLK signal that the BBP can use

when receiving the data. The DATA_CLK can be set to a rate that

provides single data rate (SDR) timing where data is sampled on

each rising clock edge, or it can be set to provide double data rate

(DDR) timing where data is captured on both rising and falling

edges. This timing applies to operation using either a single port

or both ports.

FB_CLK Signal

For transmit data, the interface uses the FB_CLK signal as the

timing reference. FB_CLK allows source synchronous timing

with rising edge capture for burst control signals and either

rising edge (SDR mode) or both edge capture (DDR mode) for

transmit signal bursts. The FB_CLK signal must have the same

frequency and duty cycle as DATA_CLK.

Data Sheet

RX_FRAME Signal

The device generates an RX_FRAME output signal whenever the

receiver outputs valid data. This signal has two modes: level

mode (RX_FRAME stays high as long as the data is valid) and

pulse mode (RX_FRAME pulses with a 50% duty cycle). Similarly,

the BBP must provide a TX_FRAME signal that indicates the

beginning of a valid data transmission with a rising edge. Similar

to the RX_FRAME, the TX_FRAME signal can remain high

throughout the burst or it can be pulsed with a 50% duty cycle.

ENABLE STATE MACHINE

The AD9361 transceiver includes an enable state machine (ENSM)

that allows real-time control over the current state of the device.

The device can be placed in several different states during normal

operation, including

• Wait—power save, synthesizers disabled

• Sleep—wait with all clocks/BB PLL disabled

• TX—TX signal chain enabled

• RX—RX signal chain enabled

• FDD—TX and RX signal chains enabled

• Alert—synthesizers enabled

The ENSM has two possible control methods: SPI control and

pin control.

SPI Control Mode

In SPI control mode, the ENSM is controlled asynchronously

by writing SPI registers to advance the current state to the next

state. SPI control is considered asynchronous to the DATA_CLK

because the SPI_CLK can be derived from a different clock

reference and can still function properly. The SPI control

ENSM method is recommended when real-time control of the

synthesizers is not necessary. SPI control can be used for real-

time control as long as the BBIC has the ability to perform

timed SPI writes accurately.

Pin Control Mode

In pin control mode, the enable function of the ENABLE pin

and the TXNRX pin allow real-time control of the current state.

The ENSM allows TDD or FDD operation depending on the

configuration of the corresponding SPI register. The ENABLE

and TXNRX pin control method is recommended if the BBIC

has extra control outputs that can be controlled in real time,

allowing a simple 2-wire interface to control the state of the

device. To advance the current state of the ENSM to the next

state, the enable function of the ENABLE pin can be driven by

either a pulse (edge detected internally) or a level.

When a pulse is used, it must have a minimum pulse width of

one FB_CLK cycle. In level mode, the ENABLE and TXNRX

pins are also edge detected by the AD9361 and must meet the

same minimum pulse width requirement of one FB_CLK cycle.

Rev. F | Page 34 of 36

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