PEREGRINE PE83336EK

PRODUCT SPECIFICATION
PE83336
Military Operating Temperature Range
3.0 GHz Integer-N PLL for Low
Phase Noise Applications
Product Description
Peregrine’s PE83336 is a high performance integer-N PLL
capable of frequency synthesis up to 3.0 GHz. The
superior phase noise performance of the PE83336 makes
it ideal for rugged military environments including: radio
handsets, radar, avionics, missiles, etc.
Features
• 3.0 GHz operation
• ÷10/11 dual modulus prescaler
• Internal phase detector
• Serial, parallel or hardwired
programmable
• Ultra-low phase noise
• Available in 44-lead CQFJ
The PE83336 features a 10/11 dual modulus prescaler,
counters and a phase comparator as shown in Figure 1.
Counter values are programmable through either a serial
or parallel interface and can also be directly hard wired.
®
Fabricated in Peregrine’s patented UTSi (Ultra Thin
Silicon) CMOS technology, the PE83336, while optimized
for stringent military environments, offers excellent RF
performance together with the economy and integration of
conventional CMOS.
Figure 1. Block Diagram
Fin
Prescaler
10 / 11
Fin
Main
Counter
fp
13
D(7:0)
8
Sdata
Pre_en
M(6:0)
A(3:0)
R(3:0)
Primary
20-bit
20
Latch
Secondary
20-bit
Latch
fr
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20
20
Phase
Detector
20
PD_U
PD_D
16
6
6
R Counter
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fc
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Page 1 of 14
PE83336
Product Specification
VDD
2
1
GND
R0
3
GND
R1
4
fr
R2
5
LD
R3
6
Enh
GND
Figure 2. Pin Configuration
44 43 42 41 40
D0, M0
7
39
fc
D1, M1
8
38
VDD_fc
D2, M2
9
37
PD_U
D3, M3
10
36
PD_D
VDD
11
35
VDD
VDD
12
34
Cext
S_WR, D4, M4
13
33
VDD
Sdata, D5, M5
14
32
Dout
Sclk, D6, M6
15
31
VDD_fp
FSELS, D7, Pre_en
16
30
fp
GND
17
29
GND
18 19 20 21 22 23 24 25 26 27 28
Fin
Fin
Hop_WR
A_WR
M1_WR
VDD
Bmode
Smode, A3
M2_WR, A2
E_WR, A1
FSELP, A0
44-lead CQFJ
Table 1. Pin Descriptions
Pin No.
(44-lead
CQFJ)
Pin
Name
Interface
Mode
Type
Description
1
VDD
ALL
(Note 1)
Power supply input. Input may range from 2.85 V to 3.15 V. Bypassing recommended.
2
R0
Direct
Input
R Counter bit0 (LSB).
3
R1
Direct
Input
R Counter bit1.
4
R2
Direct
Input
R Counter bit2.
5
R3
Direct
Input
R Counter bit3.
6
GND
ALL
(Note 1)
Ground.
D0
Parallel
Input
Parallel data bus bit0 (LSB).
M0
Direct
Input
M Counter bit0 (LSB).
D1
Parallel
Input
Parallel data bus bit1.
M1
Direct
Input
M Counter bit1.
D2
Parallel
Input
Parallel data bus bit2.
M2
Direct
Input
M Counter bit2.
D3
Parallel
Input
Parallel data bus bit3.
M3
Direct
Input
M Counter bit3.
11
VDD
ALL
(Note 1)
Same as pin 1.
12
VDD
ALL
(Note 1)
Same as pin 1.
S_WR
Serial
Input
Serial load enable input. While S_WR is “low”, Sdata can be serially clocked. Primary
7
8
9
10
13
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CMOS RFIC SOLUTIONS
PE83336
Product Specification
Pin No.
(44-lead
CQFJ)
Pin
Name
Interface
Mode
Type
Description
register data are transferred to the secondary register on S_WR or Hop_WR rising edge.
D4
Parallel
Input
Parallel data bus bit4
M4
Direct
Input
M Counter bit4
Sdata
Serial
Input
Binary serial data input. Input data entered MSB first.
D5
Parallel
Input
Parallel data bus bit5.
M5
Direct
Input
M Counter bit5.
Sclk
Serial
Input
Serial clock input. Sdata is clocked serially into the 20-bit primary register (E_WR “low”) or
the 8-bit enhancement register (E_WR “high”) on the rising edge of Sclk.
D6
Parallel
Input
Parallel data bus bit6.
M6
Direct
Input
M Counter bit6.
FSELS
Serial
Input
Selects contents of primary register (FSELS=1) or secondary register (FSELS=0) for
programming of internal counters while in Serial Interface Mode.
D7
Parallel
Input
Parallel data bus bit7 (MSB).
Pre_en
Direct
Input
Prescaler enable, active “low”. When “high”, Fin bypasses the prescaler.
GND
ALL
FSELP
Parallel
Input
Selects contents of primary register (FSELP=1) or secondary register (FSELP=0) for
programming of internal counters while in Parallel Interface Mode.
A0
Direct
Input
A Counter bit0 (LSB).
Serial
Input
Enhancement register write enable. While E_WR is “high”, Sdata can be serially clocked
into the enhancement register on the rising edge of Sclk.
Parallel
Input
Enhancement register write. D[7:0] are latched into the enhancement register on the rising
edge of E_WR.
A1
Direct
Input
A Counter bit1.
M2_WR
Parallel
Input
M2 write. D[3:0] are latched into the primary register (R[5:4], M[8:7]) on the rising edge of
M2_WR.
A2
Direct
Input
A Counter bit2.
Smode
Serial,
Parallel
Input
Selects serial bus interface mode (Bmode=0, Smode=1) or Parallel Interface Mode
(Bmode=0, Smode=0).
A3
Direct
Input
A Counter bit3 (MSB).
22
Bmode
ALL
Input
Selects direct interface mode (Bmode=1).
23
VDD
ALL
(Note 1)
Same as pin 1.
24
M1_WR
Parallel
Input
M1 write. D[7:0] are latched into the primary register (Pre_en, M[6:0]) on the rising edge of
M1_WR.
25
A_WR
Parallel
Input
A write. D[7:0] are latched into the primary register (R[3:0], A[3:0]) on the rising edge of
A_WR.
26
Hop_WR
Serial,
Parallel
Input
Hop write. The contents of the primary register are latched into the secondary register on
the rising edge of Hop_WR.
27
Fin
ALL
Input
Prescaler input from the VCO. 3.0 GHz max frequency.
28
Fin
ALL
Input
Prescaler complementary input. A bypass capacitor should be placed as close as possible
to this pin and be connected in series with a 50 Ω resistor directly to the ground plane.
29
GND
ALL
14
15
16
17
18
19
20
21
Ground.
E_WR
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Page 3 of 14
PE83336
Product Specification
Pin No.
(44-lead
CQFJ)
Pin
Name
Interface
Mode
Type
Description
30
fp
ALL
Output
Monitor pin for main divider output. Switching activity can be disabled through
enhancement register programming or by floating or grounding VDD pin 31.
31
VDD-fp
ALL
(Note 1)
VDD for fp. Can be left floating or connected to GND to disable the fp output.
32
Dout
Serial,
Parallel
Output
Data Out. The MSEL signal and the raw prescaler output are available on Dout through
enhancement register programming.
33
VDD
ALL
(Note 1)
Same as pin 1.
34
Cext
ALL
Output
Logical “NAND” of PD_U and PD_D terminated through an on chip, 2 kΩ series resistor.
Connecting Cext to an external capacitor will low pass filter the input to the inverting
amplifier used for driving LD.
35
VDD
ALL
(Note 1)
Same as pin 1.
36
PD_D
ALL
Output
PD_D is pulse down when fp leads fc.
37
PD_U
ALL
38
VDD-fc
ALL
(Note 1)
VDD for fc can be left floating or connected to GND to disable the fc output.
39
fc
ALL
Output
Monitor pin for reference divider output. Switching activity can be disabled through
enhancement register programming or by floating or grounding VDD pin 38.
40
GND
ALL
Ground.
41
GND
ALL
Ground.
42
fr
ALL
Input
Reference frequency input.
43
LD
ALL
Output
Lock detect and open drain logical inversion of CEXT. When the loop is in lock, LD is high
impedance, otherwise LD is a logic low (“0”).
44
Enh
Serial,
Parallel
Input
Enhancement mode. When asserted low (“0”), enhancement register bits are functional.
N/A
NC
ALL
PD_U is pulse down when fc leads fp.
No connection.
Note 1:
All VDD pins are connected by diodes and must be supplied with the same positive voltage level.
VDD-fp and VDD-fp are used to power the fp and fc outputs and can alternatively be left floating or connected to GND to disable the fp and fc
outputs.
Note 2:
All digital input pins have 70 kΩ pull-down resistors to ground.
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CMOS RFIC SOLUTIONS
PE83336
Product Specification
Table 2. Absolute Maximum Ratings
Symbol
Electrostatic Discharge (ESD) Precautions
Parameter/Conditions
Min
Max
Units
Supply voltage
-0.3
4.0
V
VI
Voltage on any input
-0.3
VDD
+ 0.3
V
II
DC into any input
-10
+10
mA
IO
DC into any output
-10
+10
mA
Storage temperature
range
-65
150
°C
VDD
Tstg
Latch-Up Avoidance
Unlike conventional CMOS devices, UTSi
devices are immune to latch-up.
Table 3. Operating Ratings
Symbol
®
When handling this UTSi device, observe the
same precautions that you would use with other
ESD-sensitive devices. Although this device
contains circuitry to protect it from damage due to
ESD, precautions should be taken to avoid
exceeding the rating specified in Table 4.
Parameter/Conditions
Min
Max
Units
VDD
Supply voltage
2.85
3.15
V
TA
Operating ambient
temperature range
-55
125
°C
®
CMOS
Table 4. ESD Ratings
Symbol
VESD
Note 1:
Parameter/Conditions
ESD voltage (Human Body
Model)
Level
Units
1000
V
Periodically sampled, not 100% tested. Tested per MILSTD-883, M3015 C2
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PE83336
Product Specification
Table 5. DC Characteristics
VDD = 3.0 V, -55° C ≤ TA ≤ 125° C, unless otherwise specified
Symbol
IDD
Parameter
Operational supply current;
Prescaler disabled
Prescaler enabled
Conditions
Min
Typ
Max
Units
10
20
28
mA
mA
VDD = 2.85 to 3.15 V
Digital Inputs: All except fr, R0, Fin, Fin
VIH
High level input voltage
VDD = 2.85 to 3.15 V
VIL
Low level input voltage
VDD = 2.85 to 3.15 V
IIH
High level input current
VIH = VDD = 3.15 V
IIL
Low level input current
VIL = 0, VDD = 3.15 V
0.7 x VDD
V
0.3 x VDD
V
+70
µA
µA
-1
Reference Divider input: fr
IIHR
High level input current
VIH = VDD = 3.15 V
IILR
Low level input current
VIL = 0, VDD = 3.15 V
+100
µA
µA
-100
R0 Input (Pull-up Resistor): R0
IIHRO
High level input current
VIH = VDD = 3.15 V
IILRO
Low level input current
VIL = 0, VDD = 3.15 V
+70
µA
µA
-5
Counter and phase detector outputs: fc, fp, PD_D, PD_U
VOLD
Output voltage LOW
Iout = 6mA
VOHD
Output voltage HIGH
Iout = -3mA
0.4
VDD - 0.4
V
V
Lock detect outputs: Cext, LD
VOLC
Output voltage LOW, Cext
Iout = 100uA
VOHC
Output voltage HIGH, Cext
Iout = -100uA
VOLLD
Output voltage LOW, LD
Iout = 6mA
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0.4
VDD - 0.4
V
0.4
File No. 70/0137~01A
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CMOS RFIC SOLUTIONS
PE83336
Product Specification
Table 6. AC Characteristics
VDD = 3.0 V, -55° C ≤ TA ≤ 125° C, unless otherwise specified
Symbol
Parameter
Conditions
Min
Typ
Max
Units
10
MHz
Control Interface and Latches (see Figures 3, 4, 5)
fClk
Serial data clock frequency
tClkH
Serial clock HIGH time
30
ns
tClkL
Serial clock LOW time
30
ns
tDSU
Sdata set-up time after Sclk rising edge, D[7:0] set-up
time to M1_WR, M2_WR, A_WR, E_WR rising edge
10
ns
tDHLD
Sdata hold time after Sclk rising edge, D[7:0] hold time to
M1_WR, M2_WR, A_WR, E_WR rising edge
10
ns
tPW
S_WR, M1_WR, M2_WR, A_WR, E_WR pulse width
30
ns
tCWR
Sclk rising edge to S_WR rising edge. S_WR, M1_WR,
M2_WR, A_WR falling edge to Hop_WR rising edge
30
ns
Sclk falling edge to E_WR transition
30
ns
S_WR falling edge to Sclk rising edge. Hop_WR falling
edge to S_WR, M1_WR, M2_WR, A_WR rising edge
30
ns
tEC
E_WR transition to Sclk rising edge
30
ns
tMDO
MSEL data out delay after Fin rising edge
tCE
tWRC
CL = 12 pf
8 (Note 5)
ns
Main Divider (Including Prescaler)
Fin
Operating frequency
PFin
Input level range
500
3000
MHz
External AC coupling
-5
5
dBm
External AC coupling
0
5
dBm
85°C < TA ≤ 125°C
Main Divider (Prescaler Bypassed)
Fin
Operating frequency
PFin
Input level range
50
300
MHz
External AC coupling
-5
5
dBm
External AC coupling
0
5
dBm
85°C < TA ≤ 125°C
Reference Divider
fr
Operating frequency
(Note 1)
(Note 2)
100
MHz
Pfr
Reference input power
Single ended input
-2
10
dBm
Vfr
Input sensitivity
External AC coupling
(Note 3)
0.5
VP-P
Phase Detector
fc
Comparison frequency
(Note 1)
20
MHz
SSB Phase Noise : Output Referred (Fin = 1918MHz, fr = 10 MHz, fc = 1MHz, LBW = 70 kHz)
PNOR
Output Referred Phase Noise
100 Hz Offset: VDD
= 3.0V, T = 25ºC
-78
(Note 4)
dBc/Hz
PNOR
Output Referred Phase Noise
1000 Hz Offset: VDD
= 3.0V, T = 25ºC
-94
(Note 4)
dBc/Hz
Note 1:
Parameter is guaranteed through characterization only and is not tested.
Note 2:
Running at low frequencies (< 10 MHz sinewave), the device will still be functional but may cause phase noise degradation. Inserting a lownoise amplifier to square up the edges is recommended at lower input frequencies.
Note 3:
CMOS logic levels may be used if DC coupled. For optimum phase noise performance, the reference input falling edge rate should be faster
than 80mV/ns.
Note 4:
All devices are screened to phase noise limits listed in Table 7. The magnitude of the tester uncertainty precludes testing phase noise as part
of qualification testing. These parameters are also exempt from PDA requirements.
Note 5:
Parameter is tested using 100pF load capacitance and is guaranteed through characterization only. Typical test delay is 12nS.
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Page 7 of 14
PE83336
Product Specification
Table 7. Phase Noise Test
Test name
Conditions
Max
Units
Phase Noise
100 Hz Offset
-80
dBc/Hz
1000 Hz Offset
-87
dBc/Hz
Functional Description
The PE83336 consists of a prescaler, counters, a
phase detector and control logic. The dual modulus
prescaler divides the VCO frequency by either 10 or
11, depending on the value of the modulus select.
Counters “R” and “M” divide the reference and
prescaler output, respectively, by integer values
stored in a 20-bit register. An additional counter
(“A”) is used in the modulus select logic. The phasefrequency detector generates up and down
frequency control signals. The control logic includes
a selectable chip interface. Data can be written via
serial bus, parallel bus, or hardwired direct to the
pins. There are also various operational and test
modes and lock detect.
Figure 3. Functional Block Diagram
R Counter
(6-bit)
fr
D(7:0)
Sdata
R(5:0)
Control
Logic
PD_U
Phase
Detector
M(8:0)
Control
Pins
fc
PD_D
A(3:0)
LD
Cext
2kΩ
Modulus
Select
Fin
Fin
10/11
Prescaler
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M Counter
(9-bit)
fp
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CMOS RFIC SOLUTIONS
PE83336
Product Specification
Main Counter Chain
Register Programming
The main counter chain divides the RF input
frequency, Fin, by an integer derived from the user
defined values in the “M” and “A” counters. It is
composed of the 10/11 dual modulus prescaler,
modulus select logic, and 9-bit M counter. Setting
Pre_en “low” enables the 10/11 prescaler. Setting
Pre_en “high” allows Fin to bypass the prescaler and
powers down the prescaler.
Parallel Interface Mode
The output from the main counter chain, fp, is
related to the VCO frequency, Fin, by the following
equation:
fp = Fin / [10 x (M + 1) + A]
where A ≤ M + 1, 1 ≤ M ≤ 511
(1)
When the loop is locked, Fin is related to the
reference frequency, fr, by the following equation:
Fin = [10 x (M + 1) + A] x (fr / (R+1))
where A ≤ M + 1, 1 ≤ M ≤ 511
(2)
A consequence of the upper limit on A is that Fin
must be greater than or equal to 90 x (fr / (R+1)) to
obtain contiguous channels. Programming the M
Counter with the minimum value of “1” will result in
a minimum M Counter divide ratio of “2”.
When the prescaler is bypassed, the equation
becomes:
Fin = (M + 1) x (fr / (R+1))
where 1 ≤ M ≤ 511
(3)
In Direct Interface Mode, main counter inputs M7
and M8 are internally forced low.
Reference Counter
The reference counter chain divides the reference
frequency, fr, down to the phase detector
comparison frequency, fc.
The output frequency of the 6-bit R Counter is
related to the reference frequency by the following
equation:
fc = fr / (R + 1)
where 0 ≤ R ≤ 63
(4)
Note that programming R equal to “0” will pass the
reference frequency, fr, directly to the phase
detector.
In Direct Interface Mode, R Counter inputs R4 and
R5 are internally forced low (“0”).
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Parallel Interface Mode is selected by setting the
Bmode input “low” and the Smode input “low”.
Parallel input data, D[7:0], are latched in a parallel
fashion into one of three, 8-bit primary register
sections on the rising edge of M1_WR, M2_WR, or
A_WR per the mapping shown in Table 7 on page
10. The contents of the primary register are
transferred into a secondary register on the rising
edge of Hop_WR according to the timing diagram
shown in Figure 4. Data are transferred to the
counters as shown in Table 7 on page 10.
The secondary register acts as a buffer to allow
rapid changes to the VCO frequency. This double
buffering for “ping-pong” counter control is
programmed via the FSELP input. When FSELP is
“high”, the primary register contents set the counter
inputs. When FSELP is “low”, the secondary
register contents are utilized.
Parallel input data, D[7:0], are latched into the
enhancement register on the rising edge of E_WR
according to the timing diagram shown in Figure 4.
This data provides control bits as shown in Table 8
on page 10 with bit functionality enabled by
asserting the Enh input “low”.
Serial Interface Mode
Serial Interface Mode is selected by setting the
Bmode input “low” and the Smode input “high”.
While the E_WR input is “low” and the S_WR input
is “low”, serial input data (Sdata input), B0 to B19,
are clocked serially into the primary register on the
rising edge of Sclk, MSB (B0) first. The contents
from the primary register are transferred into the
secondary register on the rising edge of either
S_WR or Hop_WR according to the timing diagram
shown in Figures 4-5. Data are transferred to the
counters as shown in Table 7 on page 10.
The double buffering provided by the primary and
secondary registers allows for “ping-pong” counter
control using the FSELS input. When FSELS is
“high”, the primary register contents set the counter
inputs. When FSELS is “low”, the secondary
register contents are utilized.
While the E_WR input is “high” and the S_WR input
is “low”, serial input data (Sdata input), B0 to B7, are
clocked serially into the enhancement register on
the rising edge of Sclk, MSB (B0) first. The
enhancement register is double buffered to prevent
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PE83336
Product Specification
inadvertent control changes during serial loading,
with buffer capture of the serially entered data
performed on the falling edge of E_WR according to
the timing diagram shown in Figure 5. After the
falling edge of E_WR, the data provide control bits
as shown in Table 8 with bit functionality enabled by
asserting the Enh input “low”.
Direct Interface Mode
Direct Interface Mode is selected by setting the
Bmode input “high”.
Counter control bits are set directly at the pins as
shown in Table 7. In Direct Interface Mode, main
counter inputs M7 and M8, and R Counter inputs R4
and R5 are internally forced low (“0”).
Table 8. Primary Register Programming
Interface
Mode
Enh
Bmode
Smode
Parallel
1
0
0
R5
R4
M8
M7 Pre_en M6
M2_WR rising edge load
M5
M4
M3
M2
M1
M0
R3
R2
M1_WR rising edge load
R1
R0
A3
A2
A1
A0
A_WR rising edge load
D3
D2
D1
D0
D7
D6
D5
D4
D3
D2
D1
D0
D7
D6
D5
D4
D3
D2
D1
D0
Serial*
1
0
1
B0
B1
B2
B3
B4
B5
B6
B7
B8
B9
B10
B11
B12
B13
B14
B15
B16
B17
B18
B19
Direct
1
1
X
0
0
0
0
Pre_en
M6
M5
M4
M3
M2
M1
M0
R3
R2
R1
R0
A3
A2
A1
A0
*Serial data clocked serially on Sclk rising edge while E_WR “low” and captured in secondary register on S_WR rising edge.
MSB (first in)
(last in) LSB
Table 9. Enhancement Register Programming
Interface
Mode
Enh
Bmode
Smode
Parallel
0
X
0
Serial*
0
X
1
Power
down
Reserved
Reserved
Reserved
D7
D6
D5
D4
B0
B1
B2
B3
Counter
load
MSEL
output
Prescaler
output
fc, fp OE
D3
D2
D1
D0
B4
B5
B6
B7
E_WR rising edge load
*Serial data clocked serially on Sclk rising edge while E_WR “high” and captured in the double buffer on E_WR falling edge.
MSB (first in)
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CMOS RFIC SOLUTIONS
PE83336
Product Specification
Figure 4. Parallel Interface Mode Timing Diagram
tDSU
tDHLD
D [7 : 0]
tPW
tCWR
tWRC
M1_WR
M2_WR
A_WR
tPW
E_WR
Hop_WR
Figure 5. Serial Interface Mode Timing Diagram
Sdata
E_WR
tEC
tCE
Sclk
S_WR
tDSU
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tClkH
tClkL
tCWR
tPW
tWRC
Copyright  Peregrine Semiconductor Corp. 2003
Page 11 of 14
PE83336
Product Specification
Enhancement Register
The functions of the enhancement register bits are shown below with all bits active “high”.
Table 10. Enhancement Register Bit Functionality
Bit Function
Bit 0
Reserved**
Bit 1
Reserved**
Description
Bit 2
Reserved**
Bit 3
Power down
Power down of all functions except programming interface.
Bit 4
Counter load
Immediate and continuous load of counter programming as directed by the Bmode and
Smode inputs.
Bit 5
MSEL output
Bit 6
Prescaler output
Bit 7
fp, fc OE
Drives the internal dual modulus prescaler modulus select (MSEL) onto the Dout output.
Drives the raw internal prescaler output onto the Dout output.
fp, fc outputs disabled.
** Program to 0
Phase Detector
The phase detector is triggered by rising edges
from the main Counter (fp) and the reference
counter (fc). It has two outputs, PD_U, and PD_D. If
the divided VCO leads the divided reference in
phase or frequency (fp leads fc), PD_D pulses “low”.
If the divided reference leads the divided VCO in
phase or frequency (fc leads fp), PD_U pulses “low”.
The width of either pulse is directly proportional to
phase offset between the two input signals, fp and
fc .
The phase detector gain is equal to 2.7 V / 2 π,
which numerically yields 0.43 V / radian.
Copyright  Peregrine Semiconductor Corp. 2003
Page 12 of 14
PD_U and PD_D drive an active loop filter which
controls the VCO tune voltage. PD_U pulses result
in an increase in VCO frequency; PD_D pulses
result in a decrease in VCO frequency (for a
positive Kv VCO).
A lock detect output, LD is also provided, via the pin
Cext. Cext is the logical “NAND” of PD_U and
PD_D waveforms, which is driven through a series
2 kohm resistor. Connecting Cext to an external
shunt capacitor provides low pass filtering of this
signal. Cext also drives the input of an internal
inverting comparator with an open drain output.
Thus LD is an “AND” function of PD_U and PD_D.
File No. 70/0137~01A
| UTSi

CMOS RFIC SOLUTIONS
PE83336
Product Specification
Figure 6. Package Drawing
44-lead CQFJ
All dimensions are in mils
Table 11. Ordering Information
Order
Code
Part
Marking
83336-21
PE83336
83336-22
83336-00
Description
Package
Shipping
Method
Packaged Part
44-lead CQFJ
26 units / Tube
PE83336
Packaged Part
44-lead CQFJ
500 units / T&R
PE83336EK
CQFJ Evaluation Board with Software
44-lead CQFJ
1 / Box
PEREGRINE SEMICONDUCTOR CORP.  |
http://www.peregrine-semi.com
Product
Status
Copyright  Peregrine Semiconductor Corp. 2003
Page 13 of 14
PE83336
Product Specification
Sales Offices
United States
Japan
Peregrine Semiconductor Corp.
Peregrine Semiconductor K.K.
6175 Nancy Ridge Drive
San Diego, CA 92121
Tel 1-858-455-0660
Fax 1-858-455-0770
5A-5, 5F Imperial Tower
1-1-1 Uchisaiwaicho,
Chiyoda-ku, Tokyo, Japan
100-011
Tel. 011-81-3-3502-5211
Fax. 011-81-3-3502-5213
Europe
Peregrine Semiconductor Europe
Aix-En-Provence Office
Parc Club du Golf, bat 9
13856 Aix-En-Provence Cedex 3
France
Tel 011-33-0-4-4239-3360
Fax 011-33-0-4-4239-7227
For a list of representatives in your area, please refer to our Web site at: http://www.peregrine-semi.com
Data Sheet Identification
Advance Information
The product is in a formative or design stage. The data sheet
contains design target specifications for product
development. Specifications and features may change in any
manner without notice.
Preliminary Specification
The data sheet contains preliminary data. Additional data
may be added at a later date. Peregrine reserves the right to
change specifications at any time without notice in order to
supply the best possible product.
Product Specification
The data sheet contains final data. In the event Peregrine
decides to change the specifications, Peregrine will notify
customers of the intended changes by issuing a PCN
(Product Change Notice).
The information in this data sheet is believed to be reliable. However,
Peregrine assumes no liability for the use of this information. Use
shall be entirely at the user’s own risk.
No patent rights or licenses to any circuits described in this
data sheet are implied or granted to any third party.
Peregrine’s products are not designed or intended for use in devices
or systems intended for surgical implant, or in other applications
intended to support or sustain life, or in any application in which the
failure of the Peregrine product could create a situation in which
personal injury or death might occur. Peregrine assumes no liability
for damages, including consequential or incidental damages, arising
out of the use of its products in such applications.
Peregrine products are protected under one or more of the following
U.S. patents: 6,090,648; 6,057,555; 5,973,382; 5,973,363; 5,930,638;
5,920,233; 5,895,957; 5,883,396; 5,864,162; 5,863,823; 5,861,336;
5,663,570; 5,610,790; 5,600,169; 5,596,205; 5,572,040; 5,492,857;
5,416,043. Other patents are pending.
Peregrine, the Peregrine logotype, Peregrine Semiconductor Corp.,
and UTSi are registered trademarks of Peregrine Semiconductor Corporation.
Copyright © 2003 Peregrine Semiconductor Corp. All rights reserved.
Copyright  Peregrine Semiconductor Corp. 2003
Page 14 of 14
File No. 70/0137~01A
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CMOS RFIC SOLUTIONS