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LT5572

1.5GHz to 2.5GHz High Linearity Direct Quadrature Modulator

Linear Technology 

LT5572

APPLICATIO S I FOR ATIO

Table 1. Typical Performance Characteristics vs VCM for fLO = 2GHz, PLO = 0dBm

VCM (V)

0.1

ICC (mA)

77

GV (dB)

–1.3

OP1dB (dBm) OIP2 (dBm) OIP3 (dBm)

0.0

47

8.3

0.2

89

–2.7

4.7

45

11.4

0.3

101

–2.1

7.1

49

15.0

0.4

113

–2.0

8.6

51

18.2

0.5

126

–1.9

9.3

52

21.2

0.6

138

–1.9

9.1

52

21.1

NFloor (dBm/Hz)

–163.2

–162.2

–160.9

–160.2

–159.2

–158.6

LOFT (dBm)

–45.6

–42.6

–42.0

–42.4

–42.4

–42.1

IR (dBc)

–42.2

–36.2

–37.0

–39.3

–41.5

–44.4

input (2VP-P,DIFF). This maximum RF output level is limited

by the 0.5VPEAK maximum baseband swing possible for a

0.5VDC common mode voltage level (assuming no extra

negative supply voltage available).

It is possible to bias the LT5572 to a common mode base-

band voltage level other than 0.5V. Table 1 shows the typical

performance for different common mode voltages.

LO section

The internal LO input amplifier performs single-ended to

differential conversion of the LO input signal. Figure 4

shows the equivalent circuit schematic of the LO input.

The internal, differential LO signal is split into in-phase

and quadrature (90° phase shifted) signals that drive LO

buffer sections. These buffers drive the double balanced I

and Q mixers. The phase relationship between the LO input

and the internal in-phase LO and quadrature LO signals

is fixed, and is independent of start-up conditions. The

phase shifters are designed to deliver accurate quadrature

signals for an LO frequency near 2GHz. For frequencies

significantly below 1.8GHz or above 2.4GHz, the quadra-

ture accuracy will diminish, causing the image rejection

VCC

LO

20pF

INPUT

ZIN ≈ 56Ω

5572 F04

Figure 4. Equivalent Circuit Schematic of the LO Input

to degrade. The LO pin input impedance is about 50Ω and

the recommended LO input power is 0dBm. For lower LO

input power, the gain, OIP2, OIP3 and dynamic range will

degrade, especially below –5dBm and at TA = 85°C. For

high LO input power (e.g., 5dBm), the LO feedthrough

will increase, without improvement in linearity or gain.

Harmonics present on the LO signal can degrade the

image rejection, because they introduce a small excess

phase shift in the internal phase splitter. For the second (at

4GHz) and third harmonics (at 6GHz) at –20dBc level, the

introduced signal at the image frequency is about –57dBc

or lower, corresponding to an excess phase shift much

less than 1 degree. For the second and third harmonics at

–10dBc, still the introduced signal at the image frequency

is about –47dBc. Higher harmonics than the third will have

less impact. The LO return loss typically will be better than

14dB over the 1.7GHz to 2.4GHz range. Table 2 shows the

LO port input impedance vs frequency.

Table 2. LO Port Input Impedance vs Frequency for EN = High

and PLO = 0dBm

FREQUENCY INPUT IMPEDANCE

S11

(MHz)

(Ω)

Mag

Angle

1000

45.9+j15.7

0.167

95

1400

60.8+j2.1

0.099

9.4

1600

63.2-j6.0

0.128

–22

1800

61.8-j14.2

0.163

–44

2000

56.4-j16.8

0.165

–61

2200

51.7-j14.7

0.144

–75

2400

47.3-j11.3

0.119

–97

2600

42.5-j8.6

0.122

–126

The input impedance of the LO port is different if the part

is in shutdown mode. The LO input impedance for EN =

Low is given in Table 3.

5572f

10

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