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THS4505 Datasheet, PDF (23/38 Pages) Texas Instruments – WIDEBAND, LOW-DISTORTION, FULLY DIFFERENTIAL AMPLIFIERS
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R1
R2
RS
VS
R3
RT
Vn −
+
+−
VP
R4
Figure 78.
Vout+
Vout−
VOCM
Equations for calculating fully differential amplifier
resistor values in order to obtain balanced operation
in the presence of a 50-Ω source impedance are
given in equations 6 through 9.
For more detailed information about balance in fully
differential amplifiers, see Fully Differential Amplifiers,
referenced at the end of this data sheet.
INTERFACING TO AN ANALOG-TO-DIGITAL
CONVERTER
The THS4500 family of amplifiers are designed
specifically
to
interface
to
today's
highest-performance analog-to-digital converters.
This section highlights the key concerns when
interfacing to an ADC and provides example
ADC/fully differential amplifier interface circuits.
Key design concerns when interfacing to an
analog-to-digital converter:
• Terminate the input source properly. In
high-frequency receiver chains, the source feed-
ing the fully differential amplifier requires a
specific load impedance (e.g., 50Ω ).
• Design a symmetric printed-circuit board layout.
Even-order distortion products are heavily influ-
enced by layout, and careful attention to a
symmetric layout will minimize these distortion
products.
• Minimize inductance in power supply decoupling
traces and components. Poor power supply de-
coupling can have a dramatic effect on circuit
performance. Since the outputs are differential,
differential currents exist in the power supply
pins. Thus, decoupling capacitors should be
placed in a manner that minimizes the impedance
of the current loop.
• Use separate analog and digital power supplies
and grounds. Noise (bounce) in the power
supplies (created by digital switching currents)
can couple directly into the signal path, and
power supply noise can create higher distortion
products as well.
• Use care when filtering. While an RC low-pass
filter may be desirable on the output of the
amplifier to filter broadband noise, the excess
THS4504
THS4505
SLOS363C – AUGUST 2002 – REVISED MARCH 2004
RT +
1
1– K
1
RS
–
2(1)K)
R3
K
+
R2
R1
R2 + R4
(6)
R3 + R1 * ǒRs || RTǓ
β1
+
R1
R1 )
R2
β2
+
R3 )
R3 ) RT
RT ||
|| RS
RS
) R4
(7)
ǒ Ǔ ǒ Ǔ VOD
VS
+
2
1–β2
β1 ) β2
RT
RT ) RS
(8)
ǒ Ǔ VOD
V IN
+
2
1–β2
β1 ) β2
(9)
loading can negatively impact the amplifier lin-
earity. Filtering in the feedback path does not
have this effect.
• AC-coupling allows easier circuit design. If
dc-coupling is required, be aware of the excess
power dissipation that can occur due to
level-shifting the output through the output com-
mon-mode voltage control.
• Do not terminate the output unless required.
Many open-loop, class-A amplifiers require 50-Ω
termination for proper operation, but closed-loop
fully differential amplifiers drive a specific output
voltage regardless of the load impedance pres-
ent. Terminating the output of a fully differential
amplifier with a heavy load adversely effects the
amplifier's linearity.
• Comprehend the VOCM input drive requirements.
Determine if the ADC's voltage reference can
provide the required amount of current to move
VOCM to the desired value. A buffer may be
needed.
• Decouple the VOCM pin to eliminate the antenna
effect. VOCM is a high-impedance node that can
act as an antenna. A large decoupling capacitor
on this node eliminates this problem.
• Be cognizant of the input common-mode range. If
the input signal is referenced around the negative
power supply rail (e.g., around ground on a single
5 V supply), then the THS4500/1 accommodates
the input signal. If the input signal is referenced
around midrail, choose the THS4502/3 for the
best operation.
• Packaging makes a difference at higher fre-
quencies. If possible, choose the smaller, ther-
mally enhanced MSOP package for the best
performance. As a rule, lower junction tempera-
tures provide better performance. If possible, use
a thermally enhanced package, even if the power
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