Corrected system performance – Atec Agilent-E8364B User Manual

5

Table 1. System Dynamic Range

a

Description

Specification
(dB) at Test
Port

b

Typical (dB) at Direct
Receiver Access Input

c

Supplemental Information

Dynamic Range (in a 10 Hz BW)

Standard Configuration and Standard Power Range (E836xB/C - Standard)

10 MHz to 45 MHz

d

79 (typical)

NA

--

45 MHz to 500 MHz

e

94

NA

--

500 MHz to 2 GHz

119

NA

--

2 GHz to 10 GHz

122

NA

--

10 GHz to 20 GHz

123

NA

--

20 GHz to 30 GHz

114

NA

--

30 GHz to 40 GHz

110

NA

--

40 GHz to 45 GHz

109

NA

--

45 GHz to 50 GHz

104

NA

--

Configurable Test Set and Standard Power Range (E836xB/C - Option 014)

10 MHz to 45 MHz

d

79 (typical)

129

45 MHz to 500 MHz

e

94

132

500 MHz to 2 GHz

119

138

2 GHz to 10 GHz

122

137

10 GHz to 20 GHz

121

136

20 GHz to 30 GHz

111

123

30 GHz to 40 GHz

107

119

40 GHz to 45 GHz

105

116

45 GHz to 50 GHz

100

111

Option 016 degrades
performance by 2 dB.

Standard Configuration and Extended Power Range & Bias-Tees (E836xB/C - Option UNL)

10 MHz to 45 MHz

d

79 (typical)

NA

45 MHz to 500 MHz

e

92

NA

500 MHz to 2 GHz

117

NA

2 GHz to 10 GHz

120

NA

10 GHz to 20 GHz

121

NA

20 GHz to 30 GHz

112

NA

30 GHz to 40 GHz

108

NA

40 GHz to 45 GHz

105

NA

45 GHz to 50 GHz

99

NA

Option 016 degrades
performance by 2 dB.

Configurable Test Set and Extended Power Range & Bias-Tees (E836xB/C - Option 014/UNL)

10 MHz to 45 MHz

d

79 (typical)

129

45 MHz to 500 MHz

e, f

92

130

500 MHz to 2 GHz

f

117

136

2 GHz to 10 GHz

f

120

135

10 GHz to 20 GHz

g

119

134

20 GHz to 30 GHz

109

121

30 GHz to 40 GHz

105

117

40 GHz to 45 GHz

101

112

45 GHz to 50 GHz

95

106

Option 016 degrades
performance by 2 dB.

a

The system dynamic range is calculated as the difference between the noise floor and the source maximum output power. System

dynamic range is a specification when the source is set to Port 1, and a characteristic when the source is set to Port 2. The effective
dynamic range must take measurement uncertainties and interfering signals into account as well as the insertion loss resulting from a thru
cable connected between Port 1 and Port 2..

b

The test port system dynamic range is calculated as the difference between the test port noise floor and the source maximum output

power. The effective dynamic range must take measurement uncertainties and interfering signals into account as well as the insertion loss
resulting from a thru cable connected between Port 1 and Port 2..

c

The direct receiver access input system dynamic range is calculated as the difference between the receiver access input noise floor and

the source maximum output power. The effective dynamic range must take measurement uncertainties and interfering signals into account.
This set-up should only be used when the receiver input will never exceed its damage level. When the analyzer is in segment sweep mode,