THS770006_10 Datasheet, PDF(22/36 Page) Texas Instruments – Broadband, Fully-Differential, 14-/16-Bit ADC DRIVER AMPLIFIER

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THS770006_10 Datasheet, PDF (22/36 Pages) Texas Instruments – Broadband, Fully-Differential, 14-/16-Bit ADC DRIVER AMPLIFIER

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THS770006

SBOS520 â JULY 2010

www.ti.com

Using the gain and knowing the full-scale input of the ADC, VADC FS, the required amplitude to drive the ADC with

the network can be calculated using Equation 3:

VAMP PP = VADC FS Â´ GAIN

(3)

Using the ADC examples given previously, Table 2 shows sample calculations of the value of RP and VAMP FS for

full-scale drive, and then for â1dB (often times, the ADC drive is backed off from full-scale in applications, so

lower amplitudes may be acceptable). All voltages are in volts, resistors in Î© (the nearest standard value should

be used), and gain as noted. Table 2 does not include the ADS5424 because no level shift is required with this

device.

ADC

ADS5485

ADS5493

ADS6149

ADS4149

VOCM

(VDC)

2.5

0 (1)

VADC

(VDC)

3.1

3.15

1.5

0.95

Table 2. Example RP for Various ADCs

VREF

(VDC)

2.5

RINT (Î©)

RO (Î©)

RP (Î©)

158.3

142.3

75.0

30.6

81.6

GAIN

(V/V)

0.73

0.71

0.60

0.38

0.62

GAIN

(dB)

â2.71

â2.93

â4.44

â8.40

â4.15

VADC FS

(VPP)

2.5

VAMP PP

FS (VPP)

4.10

3.50

3.33

5.26

3.23

VAMP PP

â1dBFS

(VPP)

3.65

3.12

2.97

4.69

2.88

(1) THS770006 with Â±2.5V supply.

The calculated values for the ADS5485 give the lowest attenuation, and because of the high VFS, it requires

3.65VPP from the amplifier to drive to â1dBFS. Performance of the THS770006 is still very good up to 130MHz at

this level, but the designer may want to further back off from full-scale for best performance and consider trading

reduced SNR performance for better SFDR performance.

The calculated values for the ADS5493 have lower attenuation as a result of reduced VFS, and requires 3.12VPP

from the amplifier to drive to â1dBFS. Performance of the THS770006 is excellent at this level up to 130MHz.

The values calculated for the ADS6149 show reasonable design targets and should work with good performance.

Note the ADS6149 does not have buffered inputs, and the inputs have equivalent resistive impedance that varies

with sampling frequency. In order to account for the increased loss, half of this resistance should be used for the

value of RINT in Equation 2.

The values calculated for the low input common-mode of the ADS4149 result in large attenuation of the amplifier

signal leading to 5.26VPP being required for full-scale ADC drive. This amplitude is greater than the maximum

capability of the device. With a single +5V supply, the THS770006 is not suitable to drive this ADC in dc-coupled

applications unless the ADC input is backed off towards â6dBFS. Another option is to operate the THS770006

with a split Â±2.5V supply, and is shown in the last row of Table 2. For this situation, if the +2.5V is used as the

pull-up voltage, only 2.88VPP is required for the â1dBFS input to the ADS4149. See the Operation with Split

Supply Â±2.5V section for more detail. Note that the ADS4149 does not have buffered inputs and the inputs have

equivalent resistive impedance that varies with sampling frequency. In order to account for the increased loss,

half of this resistance should be used for the value of RINT in Equation 2.

As with any design, testing is recommended to validate whether it meets the specific design goals.

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