AD7008/PCB 查看數據表（PDF） - Analog Devices

零件编号

产品描述 (功能)

生产厂家

AD7008/PCB

CMOS DDS Modulator

Analog Devices 

AD7008

When amplitude modulation is not required, the IQ multipliers

can be bypassed (CR = 2). The sine output is directly sent to

the 10-bit DAC.

Digital-to-Analog Converter

The AD7008 includes a high impedance current source 10-bit

DAC, capable of driving a wide range of loads at different

speeds. Full-scale output current can be adjusted, for optimum

power and external load requirements, through the use of a

single external resistor (RSET).

The DAC can be configured for single or differential-ended

operation. IOUT can be tied directly to AGND for single-ended

operation or through a load resistor to develop an output volt-

age. The load resistor can be any value required as long as the

full-scale voltage developed across it does not exceed 1 volt.

Since full-scale current is controlled by RSET, adjustments to

RSET can balance changes made to the load resistor.

DSP and MPU Interfacing

The AD7008 contains a 32-bit parallel assembly register and a

32-bit serial assembly register. Each of the modulation registers

can be loaded from either assembly register under control of the

LOAD pin and the Transfer-Control (TC) pins (See Table II).

The Command register can be loaded only from the parallel as-

sembly register. In practical use, both serial and parallel inter-

faces can be used simultaneously if the application requires.

TC3–TC0 should be stable before the LOAD signal rises and

should not change until after LOAD falls (Figure 2).

The DSP/MPU asserts both WR and CS to load the parallel as-

sembly register (Figure 3). At the end of each write, the parallel

assembly register is shifted left by 8 or 16 bits (Depending on

CR0), and the new data is loaded into the low bits. Hence, two

16-bit writes or four 8-bit writes are used to load the parallel as-

sembly register. When loading parallel data, it is only necessary

to write as much data as will be used by that register. For in-

stance, the Command Register requires only one write to the

parallel assembly register.

Serial data is input to the chip on the rising edge of SCLK, most

significant bit first (Figure 4). The data in the assembly regis-

ters can be transferred to the modulation registers by means of

the transfer control pins.

Maximum Updating of the AD7008

Updating the AD7008 need not take place in a synchronous

fashion. However, in asynchronous systems, most of the exter-

nal clock pulses (LOAD and SCLK) must be high for greater

than one system clock period. This insures that at least one

CLOCK rising edge will occur successfully completing the latch

function (Figure 1).

However, if the AD7008 is run in a synchronous mode with the

controlling DSP or microcontroller, the AD7008 may be loaded

very rapidly. Optimal speed is attained when operated in the

16-bit load mode; the following discussion will assume that

mode is used. Each of the modulation registers require two 16

bit loads. This data is latched into the parallel assembly register

on the falling edge of the WR command. This strobe is not

qualified by the CLOCK pulse but must be held low for a mini-

mum of 20 ns and only need be high for 10 ns. The two 16-bit

words may be loaded in succession. While the second 16-bit

word is being latched into the parallel assembly register, the

Transfer and Control word may be presented to the TC3–TC0

pins. If the designation register is always the same, an external

register can be used to store the information on the inputs of

TC3–TC0. At some time after the second falling edge of WR,

the LOAD signal may go high. As long as the load signal is high

5 ns (see setup time) before the rising edge of the CLOCK sig-

nal, data will be transferred to the destination register.

The limiting factor of this technique is the WR period which is

30 ns. Thus the CLOCK may run up to 33 MSPS using this

technique and the effective update rate would be one half or

16.5 MHz. See timing Figure 10 for timing details.

DATA

HI WORD

LOW WORD

WR

CLOCK

TC

LOAD

Figure 10. Accelerated Data Load Sequence

APPLICATIONS

Serial Configuration

Data is written to the AD7008 in serial mode using the two sig-

nal lines SDATA and SCLK. Data is accumulated in the serial

assembly register with the most significant bit loaded first. The

data bits are loaded on the rising edge of the serial clock. Once

data is loaded in the serial assembly register, it must be trans-

ferred to the appropriate register on chip. This is accomplished

by setting the TC bits according to Tables II and III. If you

want to load the serial assembly register into FREQ1 register,

the TC bits should be 1101. When the LOAD pin is raised,

data is transferred directly to the FREQ1 register. When oper-

ating in serial mode, some functions must still operate in parallel

mode such as loading the TC bits and updating the Command

register which is accessed only through the parallel assembly

register. See Figure 11 for a typical serial mode configuration.

+5V

U2

14 50MHz

VCC

8

OUT

VEE

7 K1115

U3

AD7008

C1

CMD0 19 D0

CMD1

CMD2

CMD3

20

21

22

23

24

D1

D2

D3

D4

D5

VREF

COMP

6

+5V

5 0.1µF C2 +5V

0.1µF

2 R4

25 D6

26 D7

IOUT 49.9

1

R3

8

9

D8

D9

IOUT

49.9

10 D10

11

12

D11

D12

13

14

D13

D14

4

R5

FSADJUST

390

15 D15

WR

LOAD

SCLK

SDATA

RESET

16 WR

TC0

TC1

TC2

TC3

27

32

33

34

35

36

41

42

31

30

38

37

CS

TC0

TC1

TC2

TC3

LOAD

SCLK

SDATA

FSELECT

CLK

RESET

SLEEP

VAA 3 +5V

VDD 17 +5V

VDD

VDD

28

39

+5V

+5V

AGND

DGND

DGND

DGND

DGND

44

7

18

29

43

TEST 40

Figure 11. General Purpose Serial Interface

REV. B

–9–

Share Link: