MITEL SL2524C

SL2524
1.3GHz Dual Wideband Logarithmic Amplifier
DS4548 - 2.1 July 1995
The SL2524 is a pin compatible replacement for the
SL2521 and SL2522 series of log amplifiers, and exhibits a
superior stability performance. The amplifier is a successive
detection type which provides linear gain and accurate logarithmic signal compression over a wide bandwidth. The two
stages can be operated independently.
When six stages (three SL2524s) are cascaded the strip
can be used for IFs between 30-650MHz whilst achieving
greater than 65dB dynamic range with a log accuracy of
<±1.0dB. The balanced limited output also offers accurate
phase information with input amplitude.
FEATURES
■
■
■
■
■
■
1.3GHz Bandwidth (-3dB)
Balanced IF limiting
3ns Rise Times/5ns Fall Times (six stages)
20ns Pulse Handling (six stages)
Temperature Stabilised
Surface Mountable
APPLICATIONS
■
■
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Ultra Wideband Log Receivers
Channelised Receivers
Monopulse Applications
OPTIONAL PIN
REFERENCE
ABSOLUTE MAXIMUM RATINGS
Supply Voltage (VCC above VEE)
+7.0V
Storage temperature
-65°C to +150°C
Operating temperature range
SL2524/B/LC
-40°C to +85°C
SL2524/C/HP
-30°C to +85°C
Junction temperature - LC20
+175°C
- HP20
+150°C
Applied DC voltage to RF input ±0.4V (between RF I/P
pins)
Applied RF power to RF input
+15dBm
NOT less than 180Ω
Value of RSET resistors
Thermal resistance:Die to case
-LC 20
28°C/W
- HP20
20°C/W
Die to ambient - LC20
73°C/W
- HP20
82°C/W
ORDERING INFORMATION
SL2524/B/LC (Ceramic leadless chip carrier package)
SL2524/C/HP (Plastic J lead chip carrier package)
SL2524/NA/1C (DC probe tested bare die)
5962 - 92315 (SMD)
PIN
DESCRIPTION
PIN
DESCRIPTION
1
2
3
4
5
6
7
8
9
10
SUB VEE
IF OUTPUT (A)
IF OUTPUT (A)
VEE (A)
OUTPUT VC (A)
IF INPUT (A)
IF INPUT (A)
VCC (A)
DET. OUTPUT (A)
R SET (A)
11
12
13
14
15
16
17
18
19
20
N/C
R SET (B)
DET. OUTPUT (B)
VCC (B)
IF OUTPUT (B)
IF OUTPUT (B)
OUTPUT VCC (B)
VEE (B)
IF INPUT (B)
IF INPUT (B)
Fig.1 Pin connections top view
SL2524
Fig.2 Circuit diagram of single stage A - (stage B pin Nos bracketed)
Fig.3 Pad map for SL2524 naked die
2
SL2524
ELECTRICAL CHARACTERISTICS - SL2524B
Guaranteed at the following test conditions unless otherwise stated
Frequency = 200MHz, Tamb = +25°C, Input power = -30dBm, VCC = 6V ±0.1V, Source Impedance = 50Ω.
Load impedance = 50Ω, Test Circuit = Fig. 4, RSET = 300Ω. Tested as a dual stage.
Characteristic
Value
Units
Conditions
Min
Typ
Max
Supply current
70
87
100
mA
Small signal gain (dual stage,
single ended)
9.6
11.4
13.0
dB
Tamb = +25°C f = 25MHz See Notes 1, 3
10.1
9.9
9.5
11.6
11.3
11.0
13.1
12.7
12.5
dB
dB
dB
Tamb = -40°C f = 200MHz See Notes 2, 3
Tamb = +25°C f = 200MHz See Note 3
Tamb = +85°C f = 200MHz See Notes 2, 3
9.7
9.3
8.2
11.2
10.7
9.7
12.7
12.1
11.2
dB
dB
dB
Tamb = -40°C f = 500MHz See Notes 2, 3
Tamb = +25°C f = 500MHz See Note 3
Tamb = +85°C f = 500MHz See Notes 2, 3
3.20
3.45
3.70
mA
3.05
3.25
3.45
mA
3.15
3.10
3.30
3.30
3.45
3.50
mA
mA
Tamb = +25°C, VIN = 0dBm, f = 25MHz
See Note 1
Tamb = -40°C, VIN = 0dBm, f = 200MHz
See Note 2
Tamb = +25°C, VIN = 0dBm, f = 200MHz
Tamb = +85°C, VIN = 0dBm, f = 200MHz
See Note 2
2.80
3.10
3.30
mA
2.90
2.85
3.15
3.10
3.45
3.65
mA
mA
Detected output current
(no signal)
0.85
0.80
0.80
0.95
0.93
0.90
1.15
1.10
1.10
mA
mA
mA
Tamb = -40°C, See Note 2
Tamb = +25°C, See Note 2
Tamb = +85°C, See Note 2
Upper cut off frequency (RF)
600
1100
MHz
900
1100
MHz
-3dB w.r.t 200MHz, Tamb = -40°C
See Note 2
-3dB w.r.t 200MHz, Tamb = +25°C
600
800
MHz
-3dB w.r.t 200MHz, Tamb = +85°C
See Note 2
MHz
-3dB w.r.t 200MHz, Tamb = +25°C
MHz
50% O/P current w.r.t. 200MHz
I/P power = 0dBm, Tamb = +25°C
Detected output current (max)
Lower cut off frequency (RF)
0.35
Detector cut off frequency
700
1
155
175
mV
0±2.0
0±3.0
Degree
-4.0±2.0
-4.0±3.0
Degree
Limited O/P var with temp.
±12
±25
mV
Noise figure
14
dB
Max I/P before overload
15
dBm
Input impedance
1
kΩ
Output impedance
50
Ω
Limited IF O/P voltage
Phase variation with input level
(normalised to -30dBm)
135
Tamb = -40°C, VIN = 0dBm, f = 500MHz
See Note 2
Tamb = +25°C, VIN = 0dBm, f = 500MHz
Tamb = +85°C, VIN = 0dBm, f = 500MHz
See Note 2
Frequency = 70MHz, -55 to +3dBm
See Note 2
Frequency = 200MHz, -55 to +3dBm
See Note 2
See Note 1
1kΩ in parallel with 2pF
NOTES
1. Parameter guaranteed but not tested
2. Tested at 25°C only, but guaranteed at temperature
3. Gain will typically increase by 6dB, when RF outputs use 1kΩ loads in place of 50Ω
3
SL2524
ELECTRICAL CHARACTERISTICS - SL2524C
Guaranteed at the following test conditions unless otherwise stated
Frequency = 200MHz, Tamb = +25°C, Input power = -30dBm, VCC = 6V ±0.1V, Source Impedance = 50Ω.
Load impedance = 50Ω, Test Circuit = Fig. 4, RSET = 300Ω. Tested as a dual stage.
Characteristic
Value
Units
Conditions
Min
Typ
Max
Supply current
70
87
100
mA
Small signal gain (dual stage,
single ended)
9.6
11.4
13.0
dB
Tamb = +25°C f = 25MHz See Note 3
9.6
9.4
9.0
11.6
11.3
11.0
13.6
13.2
13.0
dB
dB
dB
Tamb = -30°C f = 200MHz See Notes 2, 3
Tamb = +25°C f = 200MHz See Note 3
Tamb = +85°C f = 200MHz See Notes 2, 3
9.2
8.8
7.7
11.2
10.7
9.7
13.2
12.6
11.7
dB
dB
dB
Tamb = -30°C f = 500MHz See Notes 1, 3
Tamb = +25°C f = 500MHz See Note 1
Tamb = +85°C f = 500MHz See Notes 1, 3
3.20
2.95
3.45
3.25
3.70
3.55
mA
mA
3.05
3.00
3.30
3.30
3.55
3.50
mA
mA
2.70
3.10
3.30
mA
2.80
3.15
3.55
mA
2.75
3.10
3.75
mA
Tamb = +25°C, VIN = 0dBm, f = 25MHz
Tamb = -30°C, VIN = 0dBm, f = 200MHz
See Note 2
Tamb = +25°C, VIN = 0dBm, f = 200MHz
Tamb = +85°C, VIN = 0dBm, f = 200MHz
See Note 2
Tamb = -30°C, VIN = 0dBm, f = 500MHz
See Note 1
Tamb = +25°C, VIN = 0dBm, f = 500MHz
See Note 1
Tamb = +85°C, VIN = 0dBm, f = 500MHz
See Note 1
0.75
0.70
0.70
0.95
0.93
0.90
1.25
1.20
1.20
mA
mA
mA
Tamb = -30°C, See Note 2
Tamb = +25°C, See Note 2
Tamb = +85°C, See Note 2
MHz
-3dB w.r.t 200MHz, Tamb = +25°C
See Note 1
MHz
-3dB w.r.t 200MHz, Tamb = +25°C
MHz
50% O/P current w.r.t. 200MHz
mV
I/P power = 0dBm, Tamb = +25°C
Detected output current (max)
Detected output current
(no signal)
Upper cut off frequency (RF)
1000
Lower cut off frequency (RF)
0.35
Detector cut off frequency
600
Limited IF O/P voltage
Phase variation with input level
(normalised to -30dBm)
105
135
2
175
0±2.0
Degree
-4.0±2.0
Degree
Limited O/P var with temp.
±12
±25
Noise figure
14
dB
Max I/P before overload
15
dBm
Input impedance
1
kΩ
Output impedance
50
Ω
mV
NOTES
1. Parameter guaranteed but not tested
2. Tested at 25°C only, but guaranteed at temperature
3. Gain will typically increase by 6dB, when RF outputs use 1kΩ loads in place of 50Ω
4
Frequency = 70MHz, -55 to +3dBm
See Note 1
Frequency = 200MHz, -55 to +3dBm
See Note 1
See Note 1
1kΩ in parallel with 2pF
SL2524
GENERAL DESCRIPTION
The SL2524 is primarily intended for use in Radar and EW
receivers. Six stages (3 chip carriers) can be cascaded to form
a very wideband logarithmic ampifier offering >65dB of input
dynamic range, with pulse handling of better than 25ns. (See
figs 5 and 6.)
A six stange strip also offers balanced IF limiting, linearity
(log accuracy) of < ±1.0dB, temperature stabilisation and
programmable detector characteristics.
The detector has an external resistor set (RSET) pin which
allows the major characteristics of the detector to be
programmed. With six stage strip it is possible to vary the
value of RSET on each detector and so improve the overall log
error/linearity.
The detector is full wave and good slew rates are achieved
with 2ns rise and 5ns fall times (no video filter). The video
bandwidth of a six stage strip is typically 600MHz (-3dB).
The amplifier also offers balanced IF limiting, low phase
shift versus input amplitude, and at an IF of 120MHz, less than
5° of phase change is achievable over the input level of
-55dBm to +5dBm.
The IF and Video ports can be used simultaneously, so
offering phase, frequency and pulse (video) information. A
slight loss of dynamic range (2dB) will be observed when the
IF ports are used in conjunction with the video.
Fig.4 Test circuit
Fig.5 Schematic diagram showing configuration of SD Log strip
5
SL2524
Fig.6 Circuit diagram for 6-log strip (results shown in figs. 11 to 24 were achieved with this circuit)
Typical characteristics for a dual - stage amplifier (i.e. One SL2524)
Fig.7 IF Gain vs frequency of 2 amplifiers (One SL2524)
6
SL2524
Typical characteristics for a dual - stage amplifier (i.e. One SL2524) cont.
Fig.8 Normalised phase vs CW input level at 50, 250 and 450MHz for 50Ω O/P termination (25°C)
Fig.9 Detector current vs RSET at 200MHz (25°C)
7
SL2524
Typical characteristics for a dual - stage amplifier (i.e. One SL2524) cont.
Fig.10 Detector current vs frequency at RSET = 200Ω and 500Ω (25°C)
Typical characteristics for a six stage strip, using detected output (Ref. figs 5 & 6)
Fig.11 Detector bandwidth (25°C)
8
SL2524
Typical characteristics for a six stage strip, using detected output (Ref. figs 5 & 6) cont.
0
Fig.12 Detected O/P vs CW input at 60, 125, 450 and 600MHz at 25°C
Fig.13 Detected O/P vs CW input level and temperature at 60 and 125MHz
9
SL2524
Typical characteristics for a six stage strip, using detected output (Ref. figs 5 & 6) cont.
Fig.14 Detected O/P vs CW input level at 450MHz across temperature
Fig.15 Typical log linearity of detected output measured at 450MHz (25°C)
10
SL2524
Typical characteristics for a six stage strip as a low phase shift wideband limiter (Ref. figs 5 & 6)
Fig.16 IF limiting characteristics at 60MHz and 500MHz (25°C)
Fig.17 IF limiting characteristic at 60MHz across temperature
11
SL2524
Typical characteristics for a six stage strip as a low phase shift wideband limiter (Ref. figs 5 & 6)
Fig.18 IF limiting characteristic at 500MHz across temperature
Fig.19 Small signal gain vs frequency across temperature
12
SL2524
Typical characteristics for a six stage strip as a low phase shift wideband limiter (Ref. figs 5 & 6)
Fig.20 Phase deviation vs CW input level (normalised at -30dBm) at 25°C
across input frequency
Fig.21 Phase deviation vs CW input level (normalised at -30dBm) at 50MHz
across temperature
13
SL2524
Typical characteristics for a six stage strip as a low phase shift wideband limiter (Ref. figs 5 & 6)
Fig.22 Phase deviation vs CW input level (normalised at -30dBm) at 450MHz
across temperature
Fig.23 Peak phase deviation over -65dBm → +10dBm CW input level vs CW input frequency.
Across temperature
14
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