MITEL SP5769AKGQP1S

SP5769
3GHz I2C Bus Synthesiser
Preliminary information
DS4878 Issue 4.0 October 1999
Features
Ordering Information
● Complete 3·0 GHz Single Chip System
● Optimised for Low Phase Noise, with Comparison
●
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Frequencies up to 4 MHz
No RF Prescaler
Selectable Reference Division Ratio
Selectable Reference/Comparison Frequency Output
Selectable Charge Pump Current with 10:1 Ratio
Four Selectable I2C Addresses
I2C Fast Mode Compliant with 3·3V and 5V Logic Levels
Four Switching Ports
Functional Replacement for SP5659 (except ADC)
Pin Compatible with SP5655
Power Consumption 110mW with VCC = 5·5V, all Ports off
ESD Protection 2kV min., MIL-STD-883B Method 3015
Cat.1 (Normal ESD handling procedures should be
observed)
Applications
● Digital Satellite and Cable Tuning Systems
● Communications Systems
The SP5769 is a single chip frequency synthesiser
designed for tuning systems up to 3GHz. The RF
preamplifier interfaces direct with the RF programmable
divider, which is of MN1A construction so giving a step
SP5769A/KG/MP1S (Tubes)
SP5769A/KG/MP1T (Tape and Reel)
SP5769A/KG/QP1S (Tubes)
SP5769A/KG/QP1T (Tape and Reel)
size equal to the loop comparison frequency and no
prescaler phase noise degradation over the full RF
operating range. The comparison frequency is obtained
either from an on-chip crystal controlled oscillator, or from
an external source. The oscillator frequency, fREF, or phase
comparator frequency, fCOMP, can be switched to the REF/
COMP output providing a reference for a second frequency
synthesiser. The synthesiser is controlled via an 12C bus
Absolute Maximum Ratings
All voltages are referred to VEE = 0V
Supply voltage, VCC
0·3V to 17V
RF differential input voltage
2·5Vp-p
All I/O port DC offsets
20·3 to VCC 10·3V
SDA and SCL DC offset
20·3 to 6V
Storage temperature
255°C to 1125°C
Junction temperature
1150°C
MP16 thermal resistance
Chip to ambient, θJA
80°C/W
Chip to case, θJC
20°C/W
11
2
ENABLE/
SELECT
14
416/17
3
4-BIT
COUNT
1
LOCK
fPD/2
SDA
SCL
16
PUMP
CP TEST
MODE SET
2 BIT
15-BIT LATCH
ADDRESS
4 BIT
2 BIT
10
4
5
CRYSTAL CAP
REFERENCE
DIVIDER
11-BIT
COUNT
13
RF
INPUT
REF/COMP
I2C BUS
TRANSCEIVER
4-BIT LATCH AND
PORT INTERFACE
6
7
8
9
P3
P2
P1
P0
Figure 1 SP5769 block diagram
fPD/2 SELECT
3 BIT
CRYSTAL
CHARGE PUMP
DRIVE
SP5769
CHARGE PUMP
CRYSTAL CAP
CRYSTAL
SDA
SCL
PORT P3/LOGLEV
PORT P2
PORT P1
1
16
2
15
3
4
5
14
SP
5769
13
12
6
11
7
10
8
9
DRIVE
VEE
RF INPUT
RFINPUT
VCC
REF/COMP
ADDRESS
PORTP0
CHARGE PUMP
CRYSTAL CAP
CRYSTAL
SDA
SCL
PORT P3/LOGLEV
PORT P2
PORT P1
1
16
2
15
3
14
4
5
MP16
SP
5769
13
12
6
11
7
10
8
9
DRIVE
VEE
RF INPUT
RFINPUT
VCC
REF/COMP
ADDRESS
PORTP0
QP16
Figure 2 Pin connections - top view
Electrical Characteristics
Test conditions (unless otherwise stated): TAMB = 240°C to 180°C, VCC = 4·5V to 5·5V. These characteristics are
guaranteed by either production test or design. They apply within the specified ambient temperature and supply
voltage ranges unless otherwise stated.
Value
Characteristic
Supply current
RF input
Input voltage
Input impedance
SDA, SCL
Input high voltage
Pin
12
13,14
SCL clock rate
Charge pump
Output current
Output leakage
Drive output current
Crystal frequency
External reference
Input frequency
Drive level
Buffered REF/COMP
Output amplitude
Output impedance
Comparison frequency
Equivalent phase noise at
phase detector
RF division ratio
Reference division ratio
Typ.
Max.
20
25
100
40
300
300
3
2·3
0
0
5·5
5·5
1·5
1
10
210
10
Conditions
Units
mA
mVrms 100MHz to 200MHz
mVrms 200MHz to 3GHz
See Figure 4
4,5
Input low voltage
Input high current
Input low current
Leakage current
Input hysteresis
SDA output voltage
Min.
0·4
4
0·4
0·6
400
5
1
1
16
2,3
3
V
V
V
V
µA
µA
µA
V
V
V
kHz
0·5
2
20
nA
mA
MHz
2
0·2
20
0·5
MHz
Vp-p
63
610
11
0·35
250
4
2148
240
5V I2C logic selected
3·3V I2C logic selected
5V I2C logic selected
3·3V I2C logic selected
Input voltage = VCC
Input voltage = VEE
VCC = VEE
ISINK = 3mA
ISINK = 6mA
See Table 6, VPIN1 = 2V
VPIN1 = 2V, VCC = 15·0V, TAMB = 25°C
VPIN16 = 0·7V
See Figure 5 for application
Sinewave coupled via 10nF blocking capacitor
Sinewave coupled via 10nF blocking capacitor
AC coupled, see Note 2
0·0625 to 20MHz
Enabled by bit RE = 1
Vp-p
Ω
MHz
dBc/Hz SSB, within loop bandwidth, all comparison
frequencies
32767
See Table 1
cont…
2
SP5769
Electrical Characteristics (continued)
Value
Characteristic
Output Ports P3 - P0
Sink current
Leakage current
Address select
Input high current
Input low current
Logic level select
Input high level
Input low level
Input current
Pin
Min.
Typ.
Units
Conditions
10
mA
µA
1
20·5
mA
µA
1·5
10
V
V
µA
VPORT = 0·7V
VPORT = VCC See Note 1
See Table 3
VIN = VCC
VIN = VEE
See Note 3
5V I2C logic level selected or open circuit
3·3V I2C logic level selected
VIN = VEE to VCC
Max.
6-9
2
10
6
3
0
NOTES
1. Output ports high impedance on power-up, with SDA and SCL at logic ‘0’.
2. If the REF/COMP output is not used, the output should be left open circuit or connected to VCC and disabled by setting RE = ‘0’.
3. Bi-dectional port. When used as an output, the input logic state is ignored. When used as an input, the port should be switched into
high impedance (off) state.
Functional Description
The SP5769 contains all the elements necessary, with the
exception of a frequency reference, loop filter and external
high voltage transistor, to control a varactor 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 input signal is fed to an internal preamplifier, which
provides gain and reverse isolation from the divider signals.
The output of the preamplifier interfaces with the 15-bit
fully programmable divider which is of MN1A architecture,
where the dual modulus prescaler is 416/17, the A counter
is 4 bits, and the M counter is 11 bits.
The output of the programmable divider is applied to the
phase comparator where it is compared in both phase and
frequency domains with the comparison frequency. This
frequency is derived either from the on-chip 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 into 1 of 16 ratios as detailed inTable 1.
The output of the phase detector feeds a 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
programmable divider output fPD/2 can be switched to port
P0 by programming the device into test mode. The test
modes are described inTable 5.
Programming
The SP5769 is controlled by an I2C data bus and is
compatible with both standard and fast mode formats and
with I2C data generated from nominal 3·3V and 5V sources.
The I2C logic level is selected by the bi-directional port
P3/ LOGLEV. 5V logic levels are selected by connecting
P3/ LOGLEV to VCC or leaving it open circuit; 3·3V logic
levels are set by connecting P3/LOGLEV to ground. If this
port is used as an input the P3 data should be programmed
to high impedance. If used as an output only 5V logic levels
can be used, in which case the logic state imposed by the
port on the input is ignored.
Data and clock are fed in on the SDA and SCL lines
respectively as defined by I2C bus format . The synthesiser
can either accept data (write mode), or send data (read
mode). The LSB of the address byte (R/W) sets the device
into write mode if it is low, and read mode if it is high.
Tables 2 and 3 illustrate the format of the data. The device
can be programmed to respond to several addresses,
which enables the use of more than one synthesiser in an
I2C bus system. Table 4 shows how the address is selected
by applying a voltage to the address input. When the device
receives a valid address byte, it pulls the SDA line low
during the acknowledge period, and during following
acknowledge periods after further data bytes are received.
When the device is programmed into read mode, the
controller accepting the data must be pulled low during all
status byte acknowledge periods to read another status
byte. If the controller fails to pull the SDA line low during
this period, the device generates an internal STOP
condition, which inhibits further reading.
3
SP5769
R3
R2
R1
R0
Division ratio
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
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
24
5
10
20
40
80
160
320
byte data is retained. To facilitate smooth fine tuning, the
frequency data bytes are only accepted by the device after
all 15 bits of frequency data have been received, or after
the generation of a STOP condition.
Read mode
When the device is in read mode, the status byte read
from the device takes the form shown in Table 3.
Bit 1 (POR) is the power-on reset indicator, and this is set
to a logic ‘1’ if the VCC supply to the device has dropped
below 3V (at 25°C ), e.g. when the device is initially turned
on. The POR is reset to ‘0’ when the read sequence is
terminated by a STOP command. When POR is set high
this indicates the programmed information may be
corrupted and the device reset to power up condition.
Bit 2 (FL) indicates whether the device is phase locked, a
logic’1’is present if the device is locked, and a logic ‘0’ if it
is not.
Table 1 Reference division ratios
Write mode
With reference to Table 2, bytes 2 and 3 contain frequency
information bits 214-20 inclusive. Bytes 4 and 5 control the
reference divider ratio (see Table 1), charge pump setting
(see Table 6), REF/COMP output (see Table 7), output
ports and test modes (see Table 5).
Programable features
● RF programmable divider Function as described
above.
● Reference programmable divider Function as
described above.
● Charge pump current The charge pump current can
After reception and acknowledgement of a correct address
(byte 1), the first bit of the following byte determines whether
the byte is interpreted as a byte 2 or 4, a logic ‘0’ indicating
byte 2, and a logic ‘1’ indicating byte 4. Having interpreted
this byte as either byte 2 or 4, the following data byte will
be interpreted as byte 3 or 5 respectively. Having received
two complete data bytes, additional data bytes can be
entered, where byte interpretation follows the same
procedure, without re-addressing the device. This
procedure continues until a STOP condition is received.
The STOP condition can be generated after any data byte,
if however it occurs during a byte transmission, the previous
Address
Programmable divider
Programmable divider
Control data
Control data
MSB
1
0
27
1
C1
1
214
26
T2
C0
0
213
25
T1
RE
0
212
24
T0
RS
be programmed by bits C1 and C0 within data byte 5,
as defined in Table 6.
● Test mode The test modes are invoked by setting bit
T2 = 1, with selected test modes as defined by bits T1
and T0 as described in Table 5. Clock input on crystal
and RF input pins are required to invoke FL test modes.
● Reference/Comparison frequency output The
reference frequency fREF or comparison frequency fCOMP
can be switched to the REF/COMP output, function as
defined in Table 7. RE and RS default to logic’1’during
device power up, thus enabling the comparison
frequency fCOMP at the REF/COMP output.
0
211
23
R3
P3
MA1
210
22
R2
P2
MA0
29
21
R1
P1
LSB
0
28
20
R0
P0
Table 2 Write data format (MSB transmitted first)
A
MA1, MA0
214-20
R3-R0
C1, C0
RE
RS
T2-T0
P3-P0
4
Acknowledge bit
Variable address bits (see Table 4)
Programmable division ratio control bits
Reference division ratio select (see Table 1)
Charge pump current select (see Table 6)
Reference oscillator output enable
REF/COMP output select when RE=1 (see Table 7)
Test mode control bits (see Table 5)
P3, P2, P1 and P0 port output states
A
A
A
A
A
Byte 1
Byte 2
Byte 3
Byte 4
Byte 5
SP5769
MSB
1
POR
Address
Status byte
1
FL
0
0
0
0
0
0
MA1
0
MA0
0
LSB
1
0
A
A
Byte 1
Byte 2
Table 3 Read data format (MSB transmitted first)
A
MA1, MA0
POR
FL
MA1
MA0
0
0
1
1
0
1
0
1
Acknowledge bit
Variable address bits (see Table 4)
Power On Reset indicator
Phase lock flag
Address input voltage level
0 to 0·1VCC
Open circuit
0·4VCC to 0·6VCC *
0·9VCC to VCC
* Programmed by connecting a 15kΩ resistor from pin 10 to VCC
Table 4 Address selection
0
0
1
1
0
1
0
1
T1
T0
0
1
X
0
X
0
1
0
1
1
1
0
1
1
1
Current (µA)
C0
Test mode description
Normal operation
Charge pump sink
Status byte FL = logic ‘0’
Charge pump source
Status byte FL = logic ‘0’
Charge pump disable
Status byte FL = logic ‘1’
P0 = fPD/2
Table 5 Test modes
Min.
Typ.
Max.
6116
6247
6517
61087
6155
6330
6690
61450
6194
6412
6862
61812
RE
RS
0
1
1
X
0
1
Table 6 Charge pump current
REF/COMP output
High impedance
fREF selected
fCOMP selected
Table 7 REF/COMP output
300
VIN (mVRMS INTO 50Ω)
C1
T2
100
OPERATING WINDOW
40
100 200
1000
2000
FREQUENCY (MHz)
3000
4000
Figure 3 Typical RF input sensitivity
5
SP5769
j1
j0.5
j2
j0.2
j5
0
0.5
0.2
1
5
2
0·5GHz
1GHz
2j0.2
2j5
1·5GHz
2·5GHz
2j2
2j0.5
S11: ZO = 50Ω
Normalised to 50Ω
2j1
Figure 4 RF input impedance
2
68p
150p
SP5769
3
Figure 5 Crystal oscillator application
Component
Value/type
Component
Value/type
C1
C2
C3
C4
C5
C6
C7
C8
C9
C10
C11
C12
C13
C14
C15
C16
C17
C18
C19
C20
C21
18pF
2·2nF
68pF
1nF
1nF
10nF
100nF
4·7µF
100nF
100pF
1nF
100pF
100pF
4·7nF
100pF
4·7µF
10nF
39pF
100pF
1nF
1nF
C22
C23
C24
LED 1
LED 2
R1
R4
R5
R6
R7
R8
R9
R10
R11
R12
R13
R14
S1
T1
VCO
X1
100pF
4·7µF
1nF
HLMPK-150
HLMPK-150
4·7kΩ
4·7kΩ
4·7kΩ
4·7kΩ
13·3kΩ
22kΩ
1kΩ
0Ω
16Ω
16Ω
16Ω
68Ω
SW DIP-2
BCW31
POS_2000
4MHz
Table 8 Component values for Figure 6
6
SCL5
5V
SDA5
C15
6
5
4
3
J5
VCC
C13
C12
C24
18V
LED4
LED3
LED2
LED1
R6
R5
R4
R1
2
1
PORT
OUTPUTS
4 3
C18
J4
LK1
S1
X1
C1
C6
RF2
EXT REF
C2
8
7
6
5
4
3
2
1
SP
5769
9
10
11
12
13
14
15
16
R7
C3
C4
C5
VCC
CON1
ADD
R11
R9
RF3 COMP
OUTPUT
C17
C10
T1
R8
130V
R13
C21
R14
C19
VT
2
1
RF
OUT
J2
VARACTOR
C23
C8
C16
RF INPUT 18V
RF1
C22
C9
C7
VCO tuning range
= 1370MHz to 2000MHz
R12 C20
C14
R10
18V
130V
15V VCC
VCO
5
4
3
2
1
J1 POWER
CONNECTOR
SP5769
Figure 6 SP5769 evaluation board
7
SP5769
Top view
Bottom view
Figure 7 SP5769 evaluation board layout
8
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