English
Language : 

THS4541-Q1 Datasheet, PDF (41/60 Pages) Texas Instruments – 850-MHz Fully Differential Amplifier
www.ti.com
THS4541-Q1
SLOS930A – NOVEMBER 2015 – REVISED NOVEMBER 2015
Transformer input coupling allows either a single-ended or differential source to be coupled into the THS4541-
Q1; possibly also improving the input-referred noise figure. These designs assume a source impedance that
must be matched in the balun interface. The simplest approach is shown in Figure 74, where an example 1:2
turns ratio step-up transformer is used from a 50-Ω source.
Pulse
CX2047LNL
1:2 Turns Ratio
Balun
Rs
50
C1
100 nF
M1
90.4 H
+ VG1
±
N1 N2
THS4541 Wideband,
Fully-Differential Amplifier
Rf1
402
Rg1
100
Vocm
Rg2
100
Vcc
±
+
FDA
±
+
PD
Vcc
R1
500
Output
Measurement
Point
Rf2
402
Figure 74. Input Balun Interface Delivers a Differential Input to the THS4541-Q1
In this example, this 1:2 turns ratio step-up transformer provides a source and load match from the 50-Ω source
if the secondary is terminated in 200 Ω (turns-ratio squared is the impedance ratio across a balun). The two Rg
elements provide that termination as they sum to the differential virtual ground at the FDA summing junctions.
The input blocking cap (C1) is optional and included only to eliminate DC shorts to ground from the source. This
solution often improves the input-referred noise figure more so than just the FDA using this passive (zero power
dissipation) input balun. Defining a few ratios allows a noise figure expression to be written as Equation 14:
§
¨
NF
¨
10 ‡ Log¨1
¨
(1 E 2)
E2
8
DE 2
4
(DE )2
§
¨©
eni
En
‡
§
¨©
1
2
1
D
·
¸¹
·2
¸¹
1
2
kTRs
n ‡ in ‡ Rs 2
E2
·
¸
¸
¸
¸
¨©
¸¹
where
• n ≡ turns ratio (the ohms ratio is then n2)
• α ≡ differential gain in the FDA = Rf / Rg
• β ≡ transformer insertion loss in V/V (from a dB insertion loss, convert to linear attenuation = β)
• kT = 4e-21J at 290 K (17°C)
(14)
One way to use Equation 14 is to fix the input balun selection, and then sweep the FDA gain by stepping up the
Rf value. The lowest-noise method uses just the two Rg elements for termination matching (no Rm element,
such as in Figure 74) and sweep the Rf values up to assess the resulting input-referred noise figure. While this
method can be used with all FDAs and a wide range of input baluns, relatively low-frequency input baluns are an
appropriate choice here because the THS4541-Q1 holds exceptional SFDR for less than 40-MHz applications.
Two representative selections, with their typical measured spans and resulting model elements, are shown in
Table 7. For these two selections, the critical inputs for the noise figures are the turns ratio and the insertion loss
(the 0.2 dB for the CX2014LNL becomes a β = 0.977 in the NF expression).
PART
NUMBER
Rs (Ω)
ADT2-1T
50
CX2047LNL
50
Table 7. Example Input Step-Up Baluns and Associated Parameters
–1-dB
FREQUENCY
(MHz)
MIN
MAX
0.1
463
0.083
270
INSERTION
LOSS (dB)
0.3
0.2
MFR
MiniCircuits
Pulse Eng
NO. OF DECADES
–1-dB
POINTS
3.67
3.51
–3-dB
POINTS
4.22
3.93
–3-dB
FREQUENCY
(MHz)
MIN
MAX
0.05
825
0.044
372
TURNS
RATIO
L1 (µH)
MODEL ELEMENTS
L2 (µH)
k
M (µH)
1.41 79.57747 158.50797 0.99988 112.19064
2
90.42894 361.71578 0.99976 180.81512
Copyright © 2015, Texas Instruments Incorporated
Product Folder Links: THS4541-Q1
Submit Documentation Feedback
41