MITEL SP5669, SP5669KG, SP5669MP1S, SP5669MP1T Datasheet

Ordering Information

SP5669/KG/MP1S (Tubes)
SP5669/KG/MP1T (Tape and reel)

The comparison frequency is obtained either from an
on–chip crystal controlled oscillator, or from an external
source. The oscillator frequency F

ref

or the comparison

frequency F

comp

may be switched to the REF/COMP
output. This feature is ideally suited to providing the
reference frequency for a second synthesiser such as in
a double conversion tuner (see Fig. 8).

The synthesiser is controlled via an I 2 C bus, and
responds to one of four programmable addresses which
are selected by applying a specific voltage to the
‘address’ input. This feature enables two or more
synthesisers to be used in a system.

The device contains four switching ports P0–P3 and a
5–level ADC. The output of the ADC can be read via the
I 2 C
bus.

The device also contains a varactor line disable and
chargepump disable facility.

Features

● Complete 2.7GHz single chip system

● Compatible with UK DTT offset requirements

● Optimised for low phase noise

● Selectable divide by two prescaler

● Selectable reference division ratio

● Selectable reference/comparison frequency output

● Selectable charge pump current

● Four selectable I

2

C bus address

● 5–level ADC

● Pin compatible with the SP5658 3–wire bus

controlled synthesiser and SP5659 I2C bus
synthesiser and SP5659 I2C bus synthesiser
ESD protection; (Normal ESD handling
procedures should be observed)

Applications

● Complete 2.7GHz single chip system

● Optimised for low phase noise

SP5669

2.7GHz I2C Bus Controlled Synthesiser

Preliminary Information

DS4852 - Issue 2.1 May 1999

Description

The SP5669 is a single chip frequency synthesiser
designed for tuning systems up to 2.7GHz and offers
step size compatible with DTT offset requirements.

The RF preamplifier drives a divide by two prescaler
which can be disabled for applications up to 2GHz,
allowing direct interfacing with the programmable
divider so enabling a step size equal to the comparison
frequency. For applications up to 2.7GHz the divide by
two is enabled, giving a step size of twice the
comparison frequency.

2

SP5669

Figure. 1 Pin connections - top view

1161

MP16

CHARGE PUMP

CRYSTAL

REF/COMP

ADDRESS

SDA

SCL
PORT P3
PORT P2

DRIVE
Vee

RF INPUT
RF INPUT
Vcc
ADC
PORT P0
PORT P1

2
3
4
5
6
7
89

10

11

12

13

14

15

RF

1 BIT

17 BIT LA

TCH

4 BIT

LA

TCH

AND

PORT

INTERFACE

I

TRANSCEIVER

CRYSTAL

PUMP

DRIVE

ADDRESS

ADC

SDA
SCL

PORT P3 PORT P2

INPUTS

13

14

4
5
6

11

PROGRAMMABLE

DIVIDER

PUMP

REFERENCE

DIVIDER

PHASE

COMP

2 BIT

OSC 2

1

16

V

EE

15

12

V

CC

987

2/1

13 BIT

COUNT

4 BIT

COUNT

4 BIT

10

PORT P1 PORT P0

16/17

C1, C0

3

REF/COMP

3 BIT

ADC

PE

5 BIT LA

TCH and

MODE CONTROL

LOGIC

(see Fig. 5)

CHARGE

LATCHLATCH

LOCK

DETECT

LATCH

DIVIDE RA

TIO

PRE
AMP

F

L

FPD/2

P0 TEST

CONTROL

POWER ON

DETECT

POR

DISABLE

MODE

CONTROL

C

2

CHARGE

(see Fig. 3)

F

comp

F

ref

F

pd

Figure. 2 Block diagram

3

SP5669

ELECTRICAL CHARACTERISTICS

T amb = –20°C to +80°C, V

CC

= +4.5V 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.

Characteristics Pin Value Units Conditions

Min Typ Max

Supply current, I

CC

12 68 85 mA V CC = 5V prescaler enabled, PE = 1
58 73 mAV

CC

= 5V prescaler disabled, PE = 0

RF input voltage 13, 14 40 300 mV rms 300MHz to 2.7GHz Prescaled

enabled, PE = 1, See Fig. 7b.

13, 14100 300 mV rms 80MHz Prescaler enabled,

PE=1, See Fig. 7b.

13,14 50 300 mV rms 80MHz to 2.0GHz Prescaler

disabled, PE = 0, See Fig. 7a.
RF input impedance 13, 14 50 Ω Refer to Fig. 13
RF input capacitance 13, 14 2 pF Refer to Fig. 13
SDA, SCL 5, 6

Input High voltage 3 5.5 V
Input Low voltage 0 1.5 V
Input High current 10 µA Input voltage = V

CC

Input Low Current –10 µA Input voltage = V

EE

LeakageCurrent 10 µAV

CC

= V

EE

Input hysteresis 0.8 V
SDA Output voltage 5 0.4 V I sink = 3mA
Charge pump output 1 See Fig. 6, V pin = 2V
current
Charge pump output 1 ± 3 ± 10 nA V pin1 = 2V
leakage
Charge pump drive
output current 16 1 mAV pin16 = 0.7V
Drive output saturation
voltage when disabled 16 350 mV
External reference
input frequency 2 2 20 MHzAC coupled sinewave
External reference
input ampltude 2 200 500 mV p–pAC coupled sinewave
Crystal frequency 2 4 16 MHz
Crystal oscillator drive 2 35 mV p–p
level
Recommended crystal
series resistance 10 200 Ω Applies to 4MHz crystal only.

‘Parallel resonant’ crystal. Figure
quoted is under all conditions

including start up.
Crystal oscillator
negative resistance 2 400 Ω Includes temperature and

process tolerances.
REF/COMP output 3
Voltage 350 mV p–p AC coupled output. Output

enabled,RE=1. See Note 1.

4

SP5669

Electrical Chacteristics (cont.)

T amb = –20°C to 80 °C, V CC =+ 4.5V 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.

Characteristics Pin Value Units Conditions

Min Typ Max

Comparison frequency 2 MHz
Equivalent phase noise at
phase detector –148 dBC/Hz 6kHz loop BW, phase comparator

freq 250kHz. Figure measured @
1kHz offset, SSB (within loop
band width).

RF division ratio 240 131071 Prescaler disabled, PE = 0

480 262142 Prescaler enabled, PE = 1
Reference division ratio See Fig. 3
Output ports P0, P1, P2, P3 7,8,9,

10
Sink current 10 mA V port = 0.7V
Leakage current 10 µA V port = 13.2V

ADC input voltage 11 See Table 4, Fig 4
ADC input current 11 ±10 µAV

CC

≥ V input ≥ V

EE

Address input current High 4 1 mA Input voltage =V

CC

Address input current Low 4 –0.5 mA Input voltage =V

EE

Note 1: If the REF/COMP output is not used, the output should be left open circuit or connected to V CC , and disabled by
setting RE=0.

Absolute Maximum Ratings

All voltages are referred to VEE at 0V.

Characteristics Pin Value Units Conditions

Min Max

Supply Voltage, V

CC

12 0.3 7 V
RF input voltage 13,14 2.5 V p–p AC coupled as per application
RF input DC offset 13,14 –0.3 V CC +0.3 V
Port voltage 7–10 –0.3 14 V Port in off state

7–10 –0.3 6 V Port in on state
Total port current 7–10 50 mA
ADC input DC offset 11 –0.3 V CC +0.3 V
REF/COMP output DC offset 3 –0.3 V

CC

+0.3 V

Charge pump DC offset 1 –0.3 V

CC

+0.3 V

Drive DC offset 16 –0.3 V

CC

+0.3 V

Crystal oscillator DC offset 2 –0.3 V

CC

+0.3 V

Address DC offset 4 –0.3 V

CC

+0.3 V
SDA and SCL DC offset 5, 6 –0.3 6V V
Storage temperature –55 +150 °C
Junction temperature +150 °C
MP16 thermal resistance
chip to ambient 111 °C/W
chip to case 41 °C/W
Power consumption at V CC =5.5V 468 mW All ports off, prescaler enabled
ESD protection All 4 kV Mil Std 883 TM 3015

5

SP5669

Functional Description

The SP5669 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 block diagram is
shown in Fig. 2.

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
17–bit fully programmable divider via a divide–by–two
prescaler. For applications up to 2GHz RF input, the
prescaler may be disabled so eliminating the degradation
in phase noise due to prescaler action. The divider is of
MN+A architecture, where the dual modulus prescaler is
16/17, the A counter is 4–bits, and the M counter is 13–bits.

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 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 15 ratios as detailed in Fig. 3.

The output of the phase detector feeds a charge pump and
loop amplifier section, which when used with an external
voltage transistor and loop filter, integrates the current
pulses into the varactor line voltage. By invoking the
device test modes as described in Fig. 5, the varactor drive
output can be disabled so switching the external transistor
’off’ and allowing an external voltage to be written to the
varactor line for tuner alignment purposes. Similarly, the
charge pump may be also disabled to a high impedance
state.

The programmable divider output Fpd/2 can be switched
to port P0 by programming the device into test mode. The
test modes are described in Fig. 5 high

Programming

The SP5669 is controlled by an I 2 C data bus. 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 1 and 2 in Fig. 4 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 3 in Fig.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 pull the
SDA line 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.

Write Mode

With reference to Table 1, bytes 2 and 3 contain
frequency information bits 2 14 –2 0 inclusive.
Auxillary frequency bits 2 16 –2 15 are in byte 4. For
most frequencies only bytes 2 and 3 will be required.
The remainder of byte 4 and byte 5 control the
prescaler enable, reference divider ratio (see Fig. 3),
charge pump, REF/COMP output (see Fig. 5), output
ports and test modes (see Fig. 5).

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 readdressing
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 data is
retained.