MITEL SP5668KG

SP5668
2.7GHz 3-Wire Bus Controlled Synthesiser
Preliminary Information
DS4538 - 1.6 January 1997
.
The SP5668 is a single chip frequency synthesiser
designed for tuning systems up to 2.7GHz.
The RF preamplifer contains a divide by two prescaler
which can be disabled for applications up to 2GHz so enabling
a step size equal to the comparison frequency up to 2GHz and
twice the comparison frequency up to 2.7GHz.
Comparison frequencies are obtained either from a crystal
controlled on–chip oscillator or from an external source.
The device contains three switching ports, P0 – P2,
together with an ’in–lock’ flag output. Various test modes
including varactor disable and charge pump disable are also
included.
FEATURES
■ Complete 2.7GHz single chip system
■ Optimised for low phase noise
■ Selectable divide by two prescaler
■ Selectable reference division ratio
■ Charge pump disable
■ Varactor line disable
■ ‘In–lock’ flag
■ Two selectable charge pump currents
■ Three switching ports
■ Reference frequency output
■ ESD protection (Normal ESD handling procedures
should be observed)
CHARGE PUMP
CAP Q1
CRYSTAL Q2
ENABLE
DATA
CLOCK
PORT P2
PORT P1/OC
DRIVE
VEE
RF INPUT
RF INPUT
VCC
LOCK
REF
PORT P0/OC
MP16
Fig. 1 Pin connections - top view
APPLICATIONS
■ SAT, TV, VCR and Cable tuning systems
■ Communications systems
ORDERING INFORMATION
SP5668/KG/MP1S (Tubes,)
SP5668/KG/MP1T Tape and Reel)
SP5668
Fref
PROGRAMMABLE
DIVIDER
Fcomp
Fpd
13
INPUTS
14
RF
REF
PHASE
COMP
÷ 2/1
REFERENCE
DIVIDER
See Table 1
13 BIT
COUNT
÷ 16/17
OSC
CRYSTAL
Q2
1
4 BIT
COUNT
DE
CRYSTAL
Q1
16
CHARGE
PUMP
CHARGE
PUMP
DRIVE
OS
CO
1 BIT
LATCH
18 BIT LATCH
1 BIT
LATCH
3 BIT LATCH
(R0,R1,R2)
DISABLE
ENABLE 4
CLOCK 5
DATA 6
3 BIT
LATCH AND
PORT
INTERFACE
DATA
INTERFACE
1 BIT
LATCH
FLOCK
P2 P1 P0
LOCK
Fig. 2 SP5668 block diagram
ELECTRICAL CHARACTERISTICS
TAMB = 120°C to +80°C, VCC = +4.5 to +5.5V. Reference frequency = 4MHz. These characteristics are guaranteed by either
production test or design. They apply within the specified ambient temperature and supply voltage ranges unless otherwise
stated.
Characteristic
Pin
Value
Min
Supply current, Icc
RF input voltage
12
13, 14
Units
Conditions
Typ
Max
65
58
81
72
mA
mA
Vcc = 5V Prescaler enabled, PE = 1
Vcc = 5V Prescaler disabled, PE = 0
300
mVrms
100MHz Prescaler enabled, PE = 1
See Fig. 5b.
100
13, 14
40
300
mVrms
300MHz - 2.7GHz Prescaler enabled,
PE = 1, See Fig. 5b.
13,14
40
300
mVrms
100MHz to 2.0GHz Prescaler
disabled, PE = 0, See Fig. 5a
RF input impedance
Data, Clock, Enable
13, 14
4,5,6
Input high voltage
Input low voltage
See Fig. 4.
3
0
Input high current
Input low current
Hysteresis
Clock Rate
2
VCC
0.7
V
V
10
-10
µA
µA
500
mV
kHz
400
6
Input voltage = VCC
Input voltage = VEE
SP5668
ELECTRICAL CHARACTERISTICS (continued)
TAMB = 120°C to +80°C, VCC = +4.5 to +5.5V. Reference frequency = 4MHz. These characteristics are guaranteed by either
production test or design. They apply within the specified ambient temperature and supply voltage ranges unless otherwise
stated.
Characteristic
Pin
Value
Min
Bus timing
Typ
Units
Conditions
Max
4, 5, 6
Data set up , tSU
Data hold, tHD
300
600
ns
ns
See Fig. 3
See Fig. 3
Enable set up, tES
Enable hold , tEH
300
600
ns
ns
See Fig. 3
See Fig. 3
300
ns
See Fig. 3
See Table 3, Vpin1 =2V
nA
Vpin1 = 2V
mA
VPIN16 = 0.7V
350
mV
OS = 1
Clock to enable, tCE
Charge pump output
1
Current
Charge pump output
1
leakage
Drive output current
16
±10
1
Drive output saturation
Voltage when disabled
16
External reference input
frequency
3
2
20
MHz
AC coupled sinewave
External reference input
amplitude
3
200
500
mVp-p
AC coupled sinewave
Crystal frequency
Recommended crystal
3
4
10
12
200
MHz
Ω
Series resistance
Applies to 4MHz crystal only.
"Parallel resonant" crystal. Figure
quoted is under all conditions
Reference oscillator bias
3
current
REF output voltage*
10
µA
200
350
mVp-p
including start up.
See Fig. 11
AC coupled, 4MHz reference
frequency, See Fig.
Phase detector comparison
4
frequency
Equivalent phase noise at
MHz
dBc/Hz
phase detector
RF division ratio
240
131071
PE = 0, Prescaler disabled
480
262142
PE = 1, Prescaler enabled
See Table 1
Reference division ratio
Output ports P0-P2
Sink current
7-9
10
Leakage current
Lock output
Sink current
Leakage current
See **Note
mA
VPORT = 0.7V
10
µA
VPORT = 13.2V
VPIN10 = 0.7V,
10
mA
µA
1
'out of lock'
'in lock'
* REF output should be connected to VCC if unused
** Note:
1. -148dB @ 1KHz offset with 1MHz comparison frequency measured at the phase comparator.
2. When external reference is used, a high signal level is required for low phase noise.
3
SP5668
ABSOLUTE MAXIMUM RATINGS
All voltages are referred to VEE at 0V
Charateristics
Supply voltage, VCC
Pin
12
Min
-0.3
Max
7
Units
V
13, 14
13, 14
-0.3
2.5
VCC+0.3
Vp-p
V
Port output voltage
7-9
7-9
-0.3
-0.3
14
6
V
V
Total port current
REFoutput DC offset
7-9
10
-0.3
50
VCC+0.3
mA
V
Lock output DC offset
Lock output current
11
11
-0.3
VCC+0.3
10
V
mA
Charge pump DC offset
Drive DC offset
1
16
-0.3
-0.3
VCC+0.3
VCC+0.3
V
V
2, 3
4,5,6
-0.3
-0.3
VCC+0.3
VCC+0.3
V
V
-55
+150
+150
°C
°C
MP16 Thermal resistance
Chip to ambient
111
°C/W
Chip to case
Power consumption
41
407
°C/W
mV
RF input voltage
RF input offset
Crystal oscillator DC offset
Data, Clock & inputs
Storage temperature
Junction temperature
at VCC = 5.5V
ESD protection
ALL
2
kV
Conditions
Port in off state
Port in on state
All ports off, prescaler enabled
MIL-STD 883 TM3015
FUNCTIONAL DESCRIPTION
The SP5668 contains all the elements necessary, with the
exception of a frequency reference, loop filter and external
high voltage transistor, to control a varicap tuned local oscillator, so forming a complete PLL frequency synthesised
source. The device allows for operation with a high comparison frequency and is fabricated in high speed logic, which
enables the generation of a loop with good phase noise
performance. The RF preamplifier contains a selectable divide by two for operation above 2.0GHz. Up to 2GHz the RF
input interfaces directly with the programmable divider, so
eliminating degradation in phase noise due to the prescaler
action. The block diagram is shown in Fig.2.
The SP5668 is controlled by a standard 3–wire bus comprising data, clock and enable inputs. The programming word
contains 27 bits. P0 - P2 are used for port selection, 217 - 20 set
the programmable divider ratio R2 - R0 select the reference
division ratio (Table1). C0 sets the charge pump current
(Table 3) and the remaining two bits T0, OS access test modes
and disable the varactor drive (Table 2).The programming
format is shown in Fig. 3.
The clock input is disabled by an enable low signal, data is
therefore only clocked into the internal shift registers during an
enable high and is loaded into the controlling buffers by an
enable high to low transition. This load is also synchronised
with the programmable divider so giving smooth fine tuning.
4
The RF signal is fed to an internal preamplifier, which
provides gain and reverse isolation from the divider signals.
The output of the preamplifier is fed to the ÷ 2/1 selectable
prescaler and then to the 17 bit fully programmable divider,
which is of MN+A architecture. The M counter is 13 bit and the
A counter 4. If bit PE is set to a 0 the prescaler is disabled;
the control function PE cannot be used dynamically. The
output of the programmable divider is fed to the phase
comparator where it is compared in both phase and frequency
domain with the comparison frequency. This frequency is
derived either from the on board crystal controlled oscillator or
from an external source. In both cases the reference
frequency is divided down to the comparison frequency by the
reference divider which is programmable into 1 of 8 ratios as
described in Table 1.
The output of the phase comparator feeds the charge
pump and loop amplifier section, which when used with an
external high voltage transistor and loop filter integrates the
current pulses into the varactor line voltage. The charge pump
current is selected by bit C0 as described in Table 3.
The phase comparator also drives the lock detect circuit
which generates a lock flag. 'In-lock' is indicated by a high
impedance state on the lock output.
The crystal frequency Fref is available at the REF output.
This may be used as the reference for a second synthesiser
as shown in Fig. 6. The REF output is disabled by connecting
the output, pin 3, to VCC.
SP5668
PHASE NOISE
TEST MODES
The SP5668 has been designed to offer good phase noise
performance even when operated with a standard low profile
4MHz crystal and a high comparison frequency, e.g. 2MHz.
The typical phase noise performance measured in the
standard application is contained in Table 4. It has been
demonstrated that even higher levels of performance will be
achieved in a tuner application.
The programmable divider output divided by two Fpd/2 and
the comparison frequency Fcomp, can be switched to ports P0
and P1 respectively.
The charge pump can be forced to either source or sink
current, and may be disabled to high impedance state.
The varactor DRIVE output can be disabled by the OS bit
within the data word, so switching the external transistor 'OFF'
and allowing an external voltage to be written to the varactor
line for tuner alignment purposes.
The test modes are described in Table 2.
CLOCK
ENABLE
MSB
DATA
2 26 2 25 2 24 2 23 2 22 2 21 2 20 2 19 2 18 2 17 2 16
P2
P1
P0 TO OS CO R2
2
0
LSB
R1 R0 PE
FREQUENCY DATA
216 to 20
PE
R2 , R1 , R0
P2, P1, P0
CO
OS
T0
t : Programmable divider ratio control bits
: ÷2 Prescaler (Enable = 1, Disable = 0)
t : Reference divider ratio control bits (see Table 1)
t : Port control bits
t : Charge Pump current select (see Table 3)
t : Drive output disable switch
t : Test mode enable (see Table 2)
Fig. 3 Data format and timing
R2
R1
R0
RATIO
0
0
0
0
0
1
2
4
Comparison Frequency with a 4MHz
external reference
2MHz
1MHz
0
0
1
1
0
1
8
16
500kHz
250kHz
1
1
0
0
0
1
32
64
125kHz
62.5kHz
1
1
1
1
0
1
128
256
31.25kHz
15.625kHz
Table 1 Reference division ratio
P1
X
P0
X
T0
0
FUNCTIONAL DESCRIPTION
Normal operation
0
0
0
1
1
1
Charge pump sink. LOCK output = Lo Z
Charge pump source. LOCK output = Hi Z
1
1
0
1
1
1
Charge pump disable. LOCK output = Lo Z
Port P1 = Fcomp: Port 0 = Fpd/2
X = Don't care
Table 2 Test modes
5
SP5668
C0
CURRENT IN mA
0
MIN
0.23
TYP
0.30
MAX
0.37
1
0.68
0.90
1.12
Table 3 Charge pump
FLO
Fcomp
(4MHz XTAL)
RF Division
RATIO
VCO PHASE
NOISE @1kHZ
OFFSET (dBc/Hz)
EQUIVALENT
PHASE NOISE
PHASE
DETECTOR (dBc/Hz)
2GHz
2GHz
1MHz
2MHz
2000
1000
-84
-80
-146
-144
Table 4 Typical phase noise
+j1
+j0.5
+j2
+j0.2
0
+j5
0.2
0.5
1
2
5
X
X
–j0.2
–j5
X
S11:Z 0 = 50
–j0.5
X
NORMALISED TO 50Ω
–j2
–j1
Fig. 4. Typical input impedance
6
FREQUENCY MARKERS AT 100MHz,
500MHz, 1GHz AND 2.7GHz
SP5668
300
VIN
(mV RMS
INTO 50Ω)
300
VIN
(mV RMS
INTO 50Ω)
OPERATING
WINDOW
100
50
40
40
10
10
80 100
OPERATING
WINDOW
100
1000
3000 3500
2000
80 300
1000
FREQUENCY (MHz)
2000
3000 3500
2700
FREQUENCY (MHz)
Fig. 5a Typical input sensitivity (Prescaler disabled, PE=0)
Fig. 5b Typical input sensitivity (Prescaler enabled, PE=1)
1.6GHZ
50 - 900MHz
38.9MHz
1650-2700MHz
2
VCO
SP5668
SP5668
3
3
VCO
10
10nF
Fig. 6. Example of double conversion from VHF/UHF frequencies to TV IF
18pF
+30V
2
39pF
68pF
3
15nF
+5V
22k
4MHz
16k
13k3
BCW31
REFERENCE
CONTROL
MICRO
ENABLE
16
2
15
3
14
4
DATA
5
CLOCK
LOCK
1
P2
P1
SP5668
Optional application utilising
on–board crystal controlled
oscillator
+12V
47k
2n2
TUNER
1n
1n
OSCILLATOR
OUTPUT
13
12
6
11
7
10
8
9
10n
P0
Fig. 7. typical application, SP5668
7
SP5668
APPLICATION NOTES
The board can be used for the following purposes:
(A)
Measuring RF sensitivity performance.
(B)
Indicating port function
(C)
Synthesising a voltage controlled oscillator
(D)
Testing of external reference sources
A generic set of application notes AN168 for designing with
synthesisers such as the SP5668 has been written. This
covers aspects such as loop filter design and decoupling. This
application note is also featured in the Media IC Handbook.
A generic test/demo board has been produced which can
be used for the SP5668. A circuit diagram is shown in Fig. 8.
P2
+30V
+12V
+5V
C10
100nF
EXTERNAL REFERENCE
SKT2
C7
10nF
*(NOT FITTED)
C3
68pF 47µF
C2
15nF
C8
39pF
P1
ENABLE
X1 4MHz
R2
22K
R6 13K3
1
C6 18pF
2
15
3
14
4
13
12
CLOCK / SCL
6
11
7
10
8
9
LOCK
P0
P1
P2
R5 4K7
R4 4K7
R7 4K7
R6 4K7
SW1
D4 D5
8
LOCK
Fig. 8 Evaluation board
8
47K
C14
2n2F
C3
1nF
1nF
SW2
D1 D2
PIN NO : 7
16K
VAR
GND
RF INPUT
C5
5
C13
100pF
R10
T1
BCW31
47µF
C11 100nF
R9
16
DATA / SDA
C12
100pF
C9
100nF
SKT1
C4
10nF
REFERENCE
OUTPUT
SKT
SP5668
LOOP BANDWIDTH
The majority of applications for which the SP5668 is
intended require a loop filter bandwidth of between 2kHz and
10kHz.
Typically the VCO phase noise will be specified at both
1kHz and10kHz offset. It is common practice to arrange the
loop filter bandwidth such that the 1kHz figure lies within the
loop bandwidth. Thus the phase noise depends on the
synthesiser comparator noise floor, rather than the VCO.
The 10kHz offset figure should depend on the VCO
providing the loop is designed correctly, and is not
underdamped.
REFERENCE SOURCE
The SP5668 offers optimal LO phase noise performance
when operated with a large step size. This is due to the fact
that the LO phase noise within the loop bandwidth is:
phase comparator
noise floor
+ 20 log
(
LO frequency
)
phase comparator frequency
Assuming the phase comparator noise floor is flat
irrespective of sampling frequency, this means that the best
performance will be achieved when the overall LO to phase
comparator division ratio is a minimum.
There are two ways of achieving a higher phase
comparator sampling frequency:–
A) reduce the division ratio between the reference source
and the phase comparator
B) use a higher reference source frequency.
Approach B) may be preferred for best performance since it is
possible that the noise floor of the reference oscillator may
degrade the phase comparator performance if the reference
division ratio is very small.
9
SP5668
VREF
VCC
500
500
CHARGE
PUMP
RF INPUTS
200
DRIVE
OUTPUT
OS
(Output disable)
RF inputs
Loop amplifier
VCC
PORT/LOCK
25K
BIAS
Disable, Enable, Data and Clock inputs
Output Ports and Lock Output
VCC
VCC
XTAL
REF
CAP
1.2mA
Reference oscillator
Reference output
Fig.9 Input/Output interface circuits
10
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