LTC1668IG#PBF Linear Technology, LTC1668IG#PBF Datasheet - Page 14

LTC1668IG#PBF

Manufacturer Part Number

LTC1668IG#PBF

Description

IC D/A CONV 16BIT 50MSPS 28-SSOP

Manufacturer

Linear Technology

Datasheet

1.LTC1668CGPBF.pdf (24 pages)

Specifications of LTC1668IG#PBF

Settling Time

20ns

Number Of Bits

Data Interface

Parallel

Number Of Converters

Voltage Supply Source

Dual ±

Power Dissipation (max)

180mW

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

28-SSOP

Resolution (bits)

16bit

Sampling Rate

50MSPS

Input Channel Type

Parallel

Supply Voltage Range - Analog

Â± 4.75V To Â± 5.25V

Supply Current

33mA

Digital Ic Case Style

SSOP

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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APPLICATIO S I FOR ATIO

LTC1666/LTC1667/LTC1668

Operating with Reduced Output Currents

The LTC1666/LTC1667/LTC1668 are specified to operate

with full-scale output current, I

10mA down to 1mA. This can be useful to reduce power

dissipation or to adjust full-scale value. However, the DC

and AC accuracy is specified only at I

DC and AC accuracy will fall off significantly at lower I

values. At I

typically degrade to the 14-bit to 13-bit level, compared to

16-bit to 15-bit typical accuracy at 10mA I

ing I

roughly in proportion to 1/I

mance (SFDR) is affected much more by reduced I

than it is by reduced digital amplitude (see Typical Perfor-

mance Characteristics). Therefore it is usually better to

make large gain adjustments digitally, keeping I

equal to 10mA.

Output Configurations

Based on the specific application requirements, the

LTC1666/LTC1667/LTC1668 allow a choice of the best of

several output configurations. Voltage outputs can be

generated by external load resistors, transformer coupling

or with an op amp I-to-V converter. Single-ended DAC

output configurations use only one of the outputs, prefer-

ably I

Differential mode configurations use the difference be-

tween I

much better accuracy in most AC applications. Because

the DAC chip is the point of interface between the digital

input signals and the analog output, some small amount

of noise coupling to I

of that digital noise is common mode and is canceled by

the differential mode circuit. Other significant digital noise

components can be modeled as V

single-ended mode, I

is fully present at full scale. In differential mode, I

noise is cancelled at midscale input, corresponding to zero

analog output. Many AC signals, including broadband and

multitone communications signals with high peak to aver-

age ratios, stay mostly near midscale.

DIFF

OUTFS

, as shown in equation 11. Differential mode gives

OUT A

, to produce a single-ended voltage output.

from 1mA, the accuracy improves rapidly,

OUTFS

and I

= 1mA, the LTC1668 INL and DNL

OUT B

OUT A

OUTFS

to generate an output voltage,

and I

OUTFS

noise is gone at zero scale and

OUT B

OUTFS

. Note that the AC perfor-

REF

is unavoidable. Most

, from the nominal

OUTFS

or I

OUTFS

= 10mA, and

. Increas-

noise. In

OUTFS

Differential Transformer-Coupled Outputs

Differential transformer-coupled output configurations

usually give the best AC performance. An example is

shown in Figure 5. The advantages of transformer cou-

pling include excellent rejection of common mode distor-

tion and noise over a broad frequency range and conve-

nient differential-to-single-ended conversion with isola-

tion or level shifting. Also, as much as twice the power can

be delivered to the load, and impedance matching can be

accomplished by selecting the appropriate transformer

turns ratio. The center tap on the primary side of the

transformer is tied to ground to provide the DC current

path for I

average of the I

equal to avoid biasing the core. This is especially impor-

tant for compact RF transformers with small cores. The

circuit in Figure 5 uses a Mini-Circuits T1-1T RF trans-

former with a 1:1 turns ratio. The load resistance on

resistor of 50 , and the 1:1 turns ratio means the output

impedance from the transformer is 50 . Note that the

load resistors are optional, and they dissipate half of the

output power. However, in lab environments or when

driving long transmission lines it is very desirable to have

a 50 output impedance. This could also be done with a

50 resistor at the transformer secondary, but putting

the load resistors on I

it reduces the current through the transformer. At signal

frequencies lower than about 1MHz, the transformer core

size required to maintain low distortion gets larger, and at

some lower frequencies this becomes impractical.

OUT A

Figure 5. Differential Transformer-Coupled Outputs

and I

OUT A

LTC1666/

LTC1667/

LTC1668

OUT B

OUT A

OUT B

OUT A

and I

is equivalent to a single differential

and I

OUT B

OUT A

110

OUT B

. For low distortion, the DC

and I

currents must be exactly

MINI-CIRCUITS

OUT B

T1-1T

is preferred since

1666/7/8 F06

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LTC1668IG#PBF Linear Technology, LTC1668IG#PBF Datasheet - Page 14

LTC1668IG#PBF

Specifications of LTC1668IG#PBF

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