ETC HMMC-3022

Agilent HMMC-3022
DC– 12 GHz High Efficiency GaAs
HBT MMIC Divide-by-2 Prescaler
Data Sheet
Features
• Wide frequency range:
0.2–12 GHz
• High input power sensitivity:
On-chip pre- and post-amps
-20 to +10 dBm (1–8 GHz)
-15 to +10 dBm (8–10 GHz)
-10 to +4 dBm (10–12 GHz)
• Dual-mode Pout: (chip form)
0 dBm (0.5 Vp-p) @ 40 mA
Chip Size:
Chip Size Tolerance:
Chip Thickness:
Pad Dimensions:
1330 x 440 µm (52.4 x 17.3 mils)
±10 µm (± 0.4 mils)
127 ± 15 µm (5.0 ± 0.6 mils)
70 x 70 µm (2.8 x 2.8 mils)
-6.0 dBm (0.25 Vp-p) @ 30 mA
• Low phase noise:
-153 dBc/Hz @ 100 kHz offset
• (+) or (-) single supply bias
operation
• Wide bias supply range:
4.5 to 6.5 volt operating range
• Differental I/O with on-chip 50Ω
matching
Description
The HMMC-3022 GaAs HBT
MMIC prescaler offers DC to
12 GHz frequency translation for
use in communications and
EW systems incorporating
high-frequency PLL oscillator
circuits and signal-path down
conversion applications. The
prescaler provides a large input
power sensitivity window and
low phase noise. In addition to
the features listed above the
device offers an input disable
contact pad to eliminate any
self-oscillation condition.
Absolute Maximum Ratings[1]
(@ TA = 25°C, unless otherwise indicated)
Symbol
Parameters/Conditions
Units
Min.
Max.
VCC
Bias Supply Voltage
V
VEE
Bias Supply Voltage
V
[VCC-VEE]
Bias Supply Data
V
VDisable
Pre-amp Disable Voltage
V
VEE
VLogic
Logic Threshold Voltage
V
VCC –1.5
Pin (CW)
CW RF Input Power
dBm
+10
VRFin
DC Input Voltage (@ RFin or RFin Ports)
V
VCC ± 0.5
TBS[2]
Backside Operating Temperature
°C
-40
+85
Tstg
Storage Temperature
°C
-65
+165
Tmax
Max. Assembly Temp. (60 seconds max.)
°C
+7
-7
+7
VCC
VCC –1.2
310
Notes:
1. Operation in excess of any parameter limit (except TBS) may result in permanent damage to this
device.
2. MTTF >1 x106 hours @ TBS ≤ 85°C. Operation in excess of maximum operating temperature
(TBS) will degrade MTTF.
HMMC-3022 DC Specifications/Physical Properties (TA = 25°C, VCC - VEE = 5.0 volts, unless otherwise indicated)
Symbol
Parameters and Test Conditions
Units
Min.
Typ.
Max.
VCC - VEE
Operating bias supply difference[1]
V
4.5
5.0
6.5
Bias supply current (High output power configuration[2]: VPwrSel = VEE)
Bias supply current (Low output power configuration: VPwrSel = open)
mA
mA
34
25
40
30
46
35
VRFin(q)
VRFout(q)
Quiescent DC voltage appearing at all RF ports
V
VLogic
Nominal ECL Logic Level
(VLogic contact self-bias voltage, generated on-chip)
V
|ICC| or |IEE|
VCC
VCC - 1.45
VCC - 1.35
VCC - 1.25
Notes:
1. Prescaler will operate over full specified supply voltage range. VCC or VEE not to exceed limits specified in Absolute Maximum Ratings section.
2. High output power configuration: Pout = 0 dBm (Vout = 0.5 Vp-p), Low output power configuration: Pout = -6.0 dBm (Vout = 0.25 Vp-p)
RF Specifications (TA = 25°C, Z0 = 50Ω, VCC - VEE = 5.0 volts)
Symbol
Parameters and Test Conditions
ƒin(max)
Maximum input frequency of operation
ƒin(min)
Minimum input frequency of operation
(Pin = -10 dBm)
ƒSelf-Osc.
Pin
[1]
Units
Min.
Typ.
GHz
12
14
GHz
0.2
Output Self-Oscillation Frequency[2]
GHz
6.8
@ DC, (Square-wave input)
@ ƒin = 500 MHz, (Sine-wave input)
ƒin = 1 to 8 GHz
ƒin = 8 to 10 GHz
ƒin = 10 to 12 GHz
dBm
dBm
dBm
dBm
dBm
RL
Small-Signal Input/Output Return Loss
(@ƒin < 10 GHz)
dB
15
S12
Small-Signal Reverse Isolation
(@ƒin <10 GHz)
dB
30
ϕN
SSB Phase Noise (@ Pin = 0 dBm, 100 kHz offset
from a ƒout = 1.2 GHz Carrier)
dBc/Hz
-153
Jitter
Input signal time variation @ zero-crossing
(ƒin = 10 GHz, Pin = -10 dBm)
ps
1
Τr or Τf
Output edge speed (10% to 90% rise/fall time)
ps
70
-15
-15
-15
-10
-5
>-25
>-20
>-20
>-15
>-10
Max.
0.3
+10
+10
+10
+5
-1
Notes:
1. For sine-wave input signal. Prescaler will operate down to D.C. for square-wave input signal. Minimum divide frequency limited by input slew-rate.
2. Prescaler may exhibit this output signal under bias in the absence of an RF input signal. This condition may be eliminated by use of the Pre-amp Disable
(VDisable) feature, or the Differental Input de-biasing technique.
2
HMMC-3022 RF Specifications, continued
High Output Power Operating Mode [1] (TA = 25°C, ZO = 50Ω, VCC - VEE = 5.0V)
Symbol
Parameters and Test Conditions
Units
Min.
Typ.
Pout
@ ƒout < 1 GHz
@ ƒout = 2.5 GHz
@ ƒout = 5 GHz
dBm
dBm
dBm
-2.0
-2.5
-4.5
0
-0.5
-2.5
|Vout(p-p)|
@ ƒout < 1 GHz
@ ƒout = 2.5 GHz
@ ƒout = 5 GHz
volts
volts
volts
0.39
0.37
0.30
0.5
0.47
0.37
ƒout power level appearing at RFin or RFin
(@ ƒin = 10 GHz, Unused RFout or RFout unterminated)
ƒout power level appearing at RFin or RFin
(@ ƒin = 10 GHz, Both RFout & RFout terminated)
dBm
-54
PSpitback
dBm
-74
Pfeedthru
Power level of ƒin appearing at RFout or RFout
(@ ƒin = 10 GHz, Pin = 0 dBm, Referred to Pin (ƒin))
dBc
-30
H2
Second harmonic distortion output level
(@ ƒout = 2.0 GHz, Referred to Pout (ƒout))
dBc
-25
Low Output Power Operating Mode [2]
Pout
@ ƒout < 1 GHz
@ ƒout = 2.5 GHz
@ ƒout = 5 GHz
dBm
dBm
dBm
-8.0
-8.0
-10.0
-6.0
-6.0
-8.0
|Vout(p-p)|
@ ƒout < 1 GHz
@ ƒout = 2.5 GHz
@ ƒout = 5 GHz
volts
volts
volts
0.20
0.20
0.16
0.25
0.25
0.20
ƒout power level appearing at RFin or RFin
(@ ƒin = 10 GHz, Unused RFout or RFout unterminated)
ƒout power level appearing at RFin or RFin
(@ ƒin = 10 GHz, Both RFout & RFout terminated)
dBm
-63
PSpitback
dBm
-83
Pfeedthru
Power level of ƒin appearing at RFout or RFout
(@ ƒin = 10 GHz, Pin = 0 dBm, Referred to Pin (ƒin))
dBc
-30
H2
Second harmonic distortion output level
(@ ƒout = 2.0 GHz, Referred to Pout (ƒout))
dBc
-30
Notes:
1. VPwrSel = VEE .
2. VPwrSel = Open Circuit.
Post Amplifier Stage
Input Preamplifier Stage
VCC
VCC
50Ω
RFin
50Ω
50Ω
RFout
50Ω
RFout
÷2
RFin
18/36 mA
Divide Cell
VEE
VEE
VDisable
Figure 1. HMMC-3022 Simplified Schematic.
3
VPwrSel
Max.
Applications
The HMMC-3022 is designed for
use in high frequency communications, microwave instrumentation, and EW radar systems
where low phase-noise PLL
control circuitry or broad-band
frequency translation is required.
Operation
The device is designed to operate
when driven with either a singleended or differential sinusoidal
input signal over a 200 MHz to
12 GHz bandwidth. Below
200 MHz the prescaler input is
“slew-rate” limited, requiring fast
rising and falling edge speeds to
properly divide. The device will
operate at frequencies down to
DC when driven with a squarewave.
The device may be biased from
either a single positive or single
negative supply bias. The backside of the device is not DC
connected to any DC bias point
on the device.
For positive supply operation
VCC is nominally biased at any
voltage in the +4.5 to +6.5 volt
range with VEE (or VEE & VPwr-Sel)
grounded. For negative bias
operation VCC is typically
grounded and a negative voltage
between -4.5 to -6.5 volts is
applied to VEE (or VEE & VPwrSel).
Several features are designed
into this prescaler:
1) Dual-Output Power Feature
Bonding both VEE and VPwrSel
pads to either ground (positive
bias mode) or the negative
supply (negative bias mode), will
deliver ~0 dBm [0.5Vp-p] at the
RF output port while drawing
~40 mA supply current. Eliminating the VPwrSel connection
results in reduced output power
and voltage swing, -6.0 dBm
[0.25Vp-p] but at a reduced
4
current draw of ~30 mA resulting in less over-all power dissipation. (NOTE: VEE must ALWAYS
be bonded and VPwrSel must
NEVER be biased to any potential other than VEE or opencircuited.)
2) VLogic ECL Contact Pad
Under normal conditions no
connection or external bias is
required to this pad and it is selfbiased to the on-chip ECL logic
threshold voltage (VCC –1.35 V).
The user can provide an external
bias to this pad (1.5 to 1.2 volts
less than VCC) to force the
prescaler to operate at a system
generated logic threshold voltage.
3) Input Disable Feature
If an RF signal with sufficient
signal to noise ratio is present at
the RF input, the prescaler will
operate and provide a divided
output equal to the input frequency divided by the divide
modulus. Under certain “ideal”
conditions where the input is
well matched at the right input
frequency, the device may “selfoscillate”, especially under small
signal input powers or with only
noise present at the input This
“self-oscillation” will produce a
undesired output signal also
known as a false trigger. By
applying an external bias to the
input disable contact pad (more
positive than VCC –1.35 V), the
input preamplifier stage is locked
into either logic “high” or logic
“low” preventing frequency
division and any self-oscillation
frequency which may be present.
4) Input DC Offset
Another method used to prevent
false triggers or self-oscillation
conditions is to apply a 20 to
100 mV DC offset voltage between the RFin and RFin ports.
This prevents noise or spurious
low level signals from triggering
the divider.
Adding a 10 KΩ resistor between
the unused RF input to a contact
point at the VEE potential will
result in an offset of ≈25mV
between the RF inputs. Note
however, that the input sensitivity will be reduced slightly due to
the presence of this offset.
Assembly Techniques
Figure 3 shows the chip assembly
diagram for single-ended I/O
operation through 12 GHz for
either positive or negative bias
supply operation. In either case
the supply contact to the chip
must be capacitively bypassed to
provide good input sensitivity
and low input power feedthrough. Independent of the bias
applied to the device, the backside of the chip should always be
connected to both a good RF
ground plane and a good thermal
heat sinking region on the
mounting surface.
All RF ports are DC connected
on-chip to the VCC contact
through on-chip 50Ω resistors.
Under any bias conditions where
VCC is not DC grounded, the RF
ports should be AC coupled via
series capacitors mounted on the
thin-film substrate at each RF
port. Only under bias conditions
where VCC is DC grounded (as is
typical for negative bias supply
operation) may the RF ports be
direct coupled to adjacent
circuitry or in some cases, such
as level shifting to subsequent
stages. In the latter case the
device backside may be “floated”
and bias applied as the difference
between VCC and VEE.
All bonds between the device and
this bypass capacitor should be
as short as possible to limit the
inductance. For operation at
frequencies below 1 GHz, a large
value capacitor must be added to
provide proper RF bypassing.
GaAs MMICs are ESD sensitive.
ESD preventive measures must
be employed in all aspects of
storage, handling, and assembly.
Due to on-chip 50Ω matching
resistors at all four RF ports, no
external termination is required
on any unused RF port. However,
improved “Spitback” performance (~20 dB) and input sensitivity can be achieved by terminating the unused RFout port to
VCC through 50Ω (positive
supply) or to ground via a 50Ω
termination (negative supply
operation).
Agilent application note #54,
“GaAs MMIC ESD, Die Attach
and Bonding Guidelines” provides basic information on these
subjects.
MMIC ESD precautions, handling
considerations, die attach and
bonding methods are critical
factors in successful GaAs MMIC
performance and reliability.
Optional DC Operating Values/Logic Levels (TA = 25°C)
Function
Symbol
Logic Threshold[1]
Input Disable
Conditions
Min.
(volts/mA)
Typical
(volts/mA)
Max.
(volts/mA)
VLogic
VCC – 1.5
VCC – 1.35
VCC – 1.2
VDisable(High) [Disable]
VLogic + 0.25
VLogic
VCC
VDisable(Low) [Enable]
IDisable
VEE
VLogic
VLogic – 0.25
VD > VEE + 3
(VDisable – VEE – 3)/500
(VDisable – VEE – 3)/500
(VDisable – VEE – 3)/500
VD < VEE + 3
0
0
0
Note:
1. Acceptable voltage range when applied from external source.
VCC
VCC
RFin
RFout
VCC
VCC
RFin
RFout
VCCBypass
No Connection
V
VDisable EE
VPwrSel
VLogic
230
900
260
440
Notes:
• All dimensions in microns.
• All Pad Dim: 70 x 70 µm
(except where noted)
• Tolerances: ±10 µm
• Chip Thickness: 127 ± 15 µm
370
220
70
0
70
350
500
0
Figure 2. Pad Locations and Chip Dimensions.
5
650
800
950 1090
1260
1330
POSITIVE SUPPLY
To +4.5V to +6.5V VCC supply
(Bypassed via 1 µF Capacitor)
AC Coupling
Capacitor(s)
>300 pF VCC
Bypass Capacitor
3 mil nominal Gap
(@ Device Input)
AC Coupling Capacitor
(Note: Must be large enough to pass
lowest frequency output signal)
RFout
RFin
RFout
RFin
Optional
Differential Input
VEE bond required
(GND)
Optional 50Ω Termination
To VCC or GND
if AC coupling cap is employed
Optional Differential Output
OPTIONAL VPwrSel Pad Connection:
w/Pad bonded to ground: HIGH Pout Assembly
(0 dBm [0.5 Vp-p] @ ICC = 40 mA)
w/Pad NOT bonded to ground: LOW Pout Assembly
(-6.0 dBm [0.25 Vp-p] @ ICC = 30 mA)
NEGATIVE SUPPLY
3 mil nominal Gap
(@ Device Input)
RFout
RFin
Optional 50Ω Termination
RFout
RFin
Optional Differential Output
Optional
Differential Input
>300 pF VEE Bypass Capacitor
VEE bond
required
To -4.5V to -6.5V VEE supply
(Bypassed via 1 µF Capacitor)
Figure 3. Assembly Diagrams.
6
OPTIONAL VPwrSel Pad Connection:
w/Pad bonded to VEE: HIGH Pout Assembly
(0 dBm [0.5 Vp-p] @ ICC = 40 mA)
w/Pad NOT bonded to VEE: LOW Pout Assembly
(-6.0 dBm [0.25 Vp-p] @ ICC = 30 mA)
HMMC-3022 Supplemental Data
VCC – VEE = +5 V, TA = 25°C
50
TA = 25°C
0
High Power Mode
45
0
ISupply (mA)
INPUT POWER, Pin (dBm)
10
-10
-20
-30
40
-0.4
35
-0.6
-0.8
30
25
2
0
20
-1.2
15
-1.4
10
-1.6
5
-1.8
4
6
8
10
14
12
-2.0
0
16
1
2
Pin = 0 dBm, Fcarrier = 1.2 GHz
2
5
6
7
8
9
VCC –VEE = +5 V, TA = 25°C
0
-120
Pout (@ Pin = 0 dBm) (dBm)
SSB PHASE NOISE (dBc/Hz)
-115
-125
-130
-135
-140
-145
-150
-155
High Power Mode
-2
-4
-6
Low Power Mode
-8
-10
-12
-160
100
1K
10K
100K
OFFSET FROM CARRIER (Hz)
Figure 6. Typical Phase Noise Performance.
VCC – VEE = +5 V, Pin = 0 dBm, TA = 25°C
-60
Unterminated
RFout Port
-70
PSpitback (dBm)
4
Figure 5. Typical Supply Current & VLogic vs.
Supply Voltage.
Figure 4. Typical Input Sensitivity Window.
-80
-90
-100
Both RFout Ports
Terminated
-110
-120
0
2
4
6
8 10 12 14 16 18 20 22
INPUT FREQUENCY, ƒin (GHz)
Figure 8. Typical “Spitback” Power.
P(ƒout) appearing at RF input port.
7
3
VCC – VEE (V)
INPUT FREQUENCY, ƒin (GHz)
-50
-1.0
Low Power Mode
0
-40
-110
-0.2
1M
10M
-14
0
1
2
3
4
5
6
7
8
OUTPUT FREQUENCY (GHz)
Figure 7. Typical Output Power vs. Output
Frequency, ƒout (GHz).
VLogic – VCC (V)
20
This data sheet contains a variety of typical and guaranteed performance data. The information supplied should
not be interpreted as a complete list of circuit specifications. In this data sheet the term typical refers to the 50th
percentile performance. For additional information contact your local Agilent Technologies’ sales representative.
www.agilent.com/semiconductors
For product information and a complete list of
distributors, please go to our web site.
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Data subject to change.
Copyright © 2002 Agilent Technologies, Inc.
Obsoletes 5988-3193EN
June 7, 2002
5988-6155EN