MITEL SP5748KGMP1T

SP5748
2.4GHz Very Low Phase Noise PLL
Advance Information
DS4875 - 1.3 November 1998
The SP5748 is a single chip frequency synthesiser
designed for tuning systems up to 2.4 GHz and is
optimized for low phase noise with comparison
frequencies up to 4 MHz. It is designed to be downwards
software compatible with the SP5658.
Comparison frequencies are obtained either from a
crystal controlled on-chip oscillator or from an external
source. a buffered reference frequency output is also
available to drive a second SP5748.
ENABLE
DATA
CLOCK
PORT P1/OC
SPOT REF.
CRYSTAL CAP
CRYSTAL
The RF programmable divider contains a front end dual
modulus 16/17 functioning over the full operating range
and allows for coarse tuning in the upconverter
application and fine tuning in the downconverter.
14
CHARGE PUMP
DRIVE
VEE
RF INPUT
RF INPUT
VCC
REF
PORT P0/OP
MP14
Figure1 Pin connections - top view
The device also contains 2 switching ports.
APPLICATIONS
FEATURES
● TV, VCR and Cable tuning systems
● Complete 2.4 GHz single chip system
(for faster device refer to to SP5768)
● Optimised for low phase noise, with comparison
frequencies up to 4 MHz
● Communications systems
● No RF prescaler
SP5748/KG/MP1S (Tubes)
SP5748/KG/MP1T (Tape and Reel)
● Selectable reference division ratio
● Reference frequency output
● Selectable charge pump current
● Integrated loop amplifier
● Two switching ports
● Low power replacement for SP5658 and 5668
● Downwards software compatible with SP5658
● ESD protection, (Normal ESD handling
procedures should be observed)
ORDERING INFORMATION
SP5748 Advance Information
REF
13 BIT
COUNT
RF INPUT
REFERENCE
DIVIDER
CRYSTAL
16/17
4 BIT
COUNT
PUMP
DRIVE
17 BIT LATCH
DATA
CLOCK
6 BIT LATCH
3 BIT
LATCH & PORT/
TEST MODE
INTERFACE
DATA
INTERFACE
ENABLE
PORT P0/OP
PORT P1/OC
Figure 2 SP5748 block diagram
ELECTRICAL CHARACTERISTICS
These characteristics are guaranteed by either production test or design. They apply within the specified
ambient temperature and supply voltage unless otherwise stated.
TAMB = -40°C to 80°C, VCC = +4·5V to +5·5V
Characteristic
Pin
Min
Supply current
10
Value
Typ
Units
Max
13
mA
RF input frequency range 11,12
80
2400
MHz
RF input voltage
11,12
30
300
mV rms
RF input impedance
11,12
Data, clock & enable
input high voltage
input low voltage
input current
hysterysis
5,6,4
See Figure 3
3
0
-10
Vcc
0.7
10
0.8
V
V
µA
V
PP
2
Conditions
All input conditions
SP5748 Advance Information
ELECTRICAL CHARACTERISTICS (continued)
These characteristics are guaranteed by either production test or design. They apply within the specified
ambient temperature and supply voltage unless otherwise stated.
TAMB = -40°C to 80°C, VCC =+ 4·5V to +5·5V
Characteristic
Pin
Min
Clock rate
Value
Typ
6
Bus timing data set up
data hold
enable set up
enable hold
clock to enable
Units
500
kHz
5,6,4
300
600
300
600
ns
ns
ns
ns
300
ns
Charge pump output
current
1
Charge pump output
leakage
1
Charge pump drive
output current
14
0.5
Crystal frequency
Recommended crystal
2,3
2
10
Conditions
Max
See Figure4
See Figure 5,
Vpin1 = 2V
+-3
+-10
nA
Vpin1=2V
mA
Vpin 14=0.7V
20
200
MHz
Ω
See Figure 6 for application
4 MHz parallel resonant
crystal. series resistance
Oscillator temperature
stability
TBC
o
ppm/ C
Oscillator supply voltage
stability
TBC
ppm/V
External reference input
frequency
2
2
20
MHz
Sinewave coupled through
TBA nF blocking capacitor
External reference drive
2
0.2
0.5
Vpp
Sinewave coupled through
level
Buffered reference
frequency output *
output amplitude
output impedance
TBA nF blocking capacitor
9
AC coupled
0.35
TBC
Vpp
Ω
2-20MHz
3
SP5748 Advance Information
ELECTRICAL CHARACTERISTICS
These characteristics are guaranteed by either production test or design. They apply within the specified
ambient temperature and supply voltage unless otherwise stated.
TAMB = -40°C to 80°C, VCC = +4·5V to +5·5V
Characteristic
Pin
Value
Min
Typ
Comparison frequency
Units
Max
4
Equivalent phase noise at
phase detector
-148
RF division ratio
240
MHz
dBc/Hz
@10 kHz, SSB, with 2 MHz
comparison from 4 MHz crystal
reference
131071
Reference division ratio
Output ports P0-P1#
sink current
leakage current
Conditions
see figure (7)
7, 8
2
10
µA
mA
Vport = 0.7V
Vport = Vcc
* Reference output disabled by connecting to Vcc if not required
’ Output ports high impedance on power up, with data, clock and enable at logic 0
4
SP5748 Advance Information
ABSOLUTE MAXIMUM RATINGS
All voltages are referred to VEE at 0V
Characteristic
Supply voltage, Vcc
Pin
Min
10
-0.3
RF input voltage
11,12
RF input DC offset
11,12
-0.3
7,8
-0.3
Charge pump DC offset
1
-0.3
Varactor drive DC offset
14
-0.3
Crystal DC offset
2,3
-0.3
9
5,6,4
Port voltage
Buffered ref output
Data, clock & enable
DC offset
Storage temperature
Max
Units
7
V
2.5
Vp-p
V
Vcc+0.3
Vcc+0.3
V
V
-0.3
Vcc+0.3
Vcc+0.3
-0.3
Vcc+0.3
V
-55
+125
°C
+150
°C
81
27
°C/W
°C/W
TBC
mW
MP14 thermal resistance,
chip to ambient
chip to case
2
Conditions
Differential across pins
11 and 12
V
Vcc+0.3
Vcc+0.3
Junction temperature
Power consumption at
Vcc=5.5V
ESD protection
Typ
V
V
kV
All ports off
Mil-std 883B latest revision
method 3015 cat.1.
Functional description
The SP5748 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 excellent phase noise
performance, even with high comparison frequencies.
The package and pin allocation is shown in Figure 1 and
the block diagram in Figure 2.
The SP5748 is controlled by a standard 3-wire bus
comprising data, clock and enable inputs. The
programming word contains 26 bits, two of which are
used for port selection, 17 to set the programmable
divider ratio, four bits to select the reference division
ratio, bits RD & R0-R2, see Figure 7, two bits to set
charge pump current, bit C0 and C1, see Figure 5, and
the remaining bit to access test modes, bit T0, see
Figure 8. The programming format is shown in Figure 4.
The clock input is disabled by an enable low signal, data
is therefore only loaded into the internal shift registers
during an enable high and is clocked 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.
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 17 bit
fully programmable counter, which is of MN+A
architecture. The M counter is 13 bit and the A counter
4
The output of the programmable counter 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
reference source. In both cases the reference
frequency is divided down to the comparison frequency
by the reference divider which is programmable into1 of
16 ratios as descried in Figure 7.
The output of the phase detector 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 setting is described in Figure 5,
A buffered crystal reference frequency suitable for
driving further synthesisers is available from pin 9. If not
required this output can be disabled by connecting to
Vcc
The programmable divider output divided by 2, Fpd/2
and comparison frequency, Fcomp can be switched to
ports P0 and P1 respectively by switching the device
into test mode. The test modes are described in Figure
8.
5
SP5748 Advance Information
+j1
+j2
+j0.5
+j0.2
+j5
0
1
2
-j0.2
S11 : Zo = 50Ω
4
-j0.5
Normalised to 50Ω
-j5
3
Frequency Markers at 500MHz,
-j2
1GHz, 1.5GHz and 2.4GHz
-j1
Figure 3 RF input impedance
CLOCK
ENABLE
DATA
225
P1
224
223
222
221
P0
T0
C1
C0
220
R2
219
218
R1
R0
217
RD
216
MSB
LSB
Frequency data
TIMING DIAGRAM
TBC
2^16 to 2^0
:
Programmable divider ratio control bits
R2,R1,R0
:
Reference divider control bits
RD
:
Reference divider mode select
P1,P0
:
Port control bits
C1,C0
:
Charge pump current select
T0
:
Test mode enable
Figure 4 Data format
C1
C0
Current (in mA)
0
0
0.2
0
1
0.9
1
0
.1
1
1
.45
Figure 5 Charge pump current
6
20
SP5748 Advance Information
2
SP5748
3
Figure 6 Crystal oscillator application
RD
0
0
0
0
0
0
0
0
R2
0
0
0
0
1
1
1
1
R1
0
0
1
1
0
0
1
1
R0
0
1
0
1
0
1
0
1
RATIO
2
4
8
16
32
64
128
256
1
1
1
1
1
1
1
1
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
3
5
10
20
40
80
160
320
Figure 7 Reference division ratio
P1
X
0
0
1
1
P0
X
0
1
0
1
T0
0
1
1
1
1
FUNCTIONAL DESCRIPTION
Normal operation
Charge pump sink
Charge pump source
Charge pump disable
Port P1 = Fcomp, P0 = Fpd/1
X = don't care
Figure 8 Test modes
7
SP5748 Advance Information
300
VIN
(mV RMS
INTO 50Ω)
OPERATING
WINDOW
30
10
1000
80
2400
FREQUENCY (MHz)
Figure 9 Typical input sensitivity
1.6GHz
50 - 900MHz
38.9MHz
1650-2700MHz
1650 -2400MHz
2
VCO
SP5748
SP5748
3
3
VCO
10
10nF
Figure 10 Example of double conversion from VHF/UHF frequencies to TV IF
18pF
+30V
2
39pF
68pF
3
15nF
+5V
22k
4MHz
16k
13k3
BCW31
Optional application utilising
on–board crystal controlled
oscillator
ENABLE
DATA
2
13
3
12
4
5
CLOCK
P1
SP5748
CONTROL
MICRO
2n2
TUNER
1n
1n
OSCILLATOR
OUTPUT
11
10
6
9
7
8
10n
P0
Figure 11 Typical application SP5748
8
47k
14
1
REFERENCE
+12V
SP5748 Advance Information
APPLICATION NOTES
REFERENCE SOURCE
A generic set of application notes AN168 for designing
withsynthesisers such as the SP5748 has been written.
This covers aspects such as loop filter design and
decoupling. Thisapplication note is also featured in the
Media Data Book, or refer to the Mitel Semiconductor
Internet Site http://www.Mitelsemi.com. A generic test/
demo board has been produced which can be used for
the SP5748. A circuit diagram is shown in Figure 12.
The SP5748 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:
The board can be used for the following purposes:
(A) Measuring RF sensitivity performance.
(B) Indicating port function.
(C) Synthesising the voltage controlled oscillator.
(D) Testing of external reference.
(E) Measurement of phase noise performance.
phase comparator
LO frequency
noise floor
+ 20 log 10 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.
LOOP BANDWIDTH
The majority of applications for which the SP5748 is
intended require a loop filter bandwidth of between
2kHz and10kHz.
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.
9
)
Clock
GND
Enable
Data
3 WIRE BUS
J5
6
5
4
3
C12
C13
C15
100pF 100pF 100pF
8V
C11
1nF
HLMPK-150
LED2
HLMPK-150
LED1
10nF
C6
RF2 EXT REF
4K7
R4
4K7
R1
1
R6
POT2
2
LK2 LK
18pF
C1
1
2
1
SW DIP-2
S1
2
4
3
X1
4MHz
39pF
C18
7
6
5
4
3
2
1
1
2
J4
C2
2n2F
P0
REF OUT
VCC
RF Input
RF Input
VEE
PORT OUTPUTS
P1
CLK
DATA
ENA
XTAL
XTAL CAP
Drive Output
IC1
SP5748
CP
NF
C3
8
9
10
11
12
13
14
C17
10nF
Figure 12 Evaluation Board
LK2 TO BE FITTED FOR NORMAL OPERATION
W
R7
13K3
C9
100nF
C8
4u7F
1nF
R13
16R
16R
16R
RF3 COMP O/P
C4
R12
R11
1nF
C21
0R
1K
C14
4n7F
R10
C5 1nF
VCC
LK1
LK
+8V
+22V
+5V
POWER CONNECTOR
1
2
3
4
5
J1
R9
8V
VCC
T1
BCW31
R8
22K
2
1
1nF
C20
1
2
C19
100pF
1
8V
VARACTOR
RF INPUT RF1
J2
+8V
R14
68R
GND
POS_2000
7
POS_2000
POS-2000 TUNING RANGE = 1370MHz - 2000MHz
8
VT
RF OUT
10
2
C7
C10
C16
100nF 100pF 4u7F
SP5748 Advance Information
SP5748 Advance Information
Top view
Bottom view
Figure 13
11
SP5748 Advance Information
VREF
VCC
500
500
CHARGE
PUMP
RF INPUTS
200
RF inputs
Loop amplifier
VCC
PORT
25K
BIAS
Disable, Enable, Data and Clock inputs
Output Ports
VCC
VCC
CRYSTAL
REF
1.2mA
CRYSTAL CAP
Reference oscillator
Reference output
Figure 14 Input/Output interface cicruits
12
DRIVE
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