MITEL SP5669KGMP1S

SP5669
2.7GHz I2C Bus Controlled Synthesiser
Preliminary Information
DS4852 - 1.4 November 1997
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.
The comparison frequency is obtained either from an on–
chip crystal controlled oscillator, or from an external source.
The oscillator frequency Fref or the comparison frequency
Fcomp 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 charge
pump 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 I2C 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
■ SAT, TV, VCR and Cable tuning systems
CHARGE PUMP
1
16
DRIVE
CRYSTAL
2
15
Vee
REF/COMP
3
14
RF INPUT
ADDRESS
4
13
RF INPUT
SDA
5
12
Vcc
SCL
6
11
ADC
PORT P3
7
10
PORT P0
PORT P2
8
9
PORT P1
MP16
Fig.1 Pin connections - top view
APPLICATIONS
■ Complete 2.7GHz single chip system
■ Optimised for low phase noise
ORDERING INFORMATION
SP5669/KG/MP1S (Tubes)
SP5669/KG/MP1T (Tape and reel)
SP5669
3 REF/COMP
13
PRE
AMP
Fpd
13 BIT
COUNT
Fref
REFERENCE
DIVIDER
(see Fig. 3)
PHASE
COMP
2 CRYSTAL
OSC
16/17
2/1
LOCK
DETECT
14
1
4 BIT
COUNT
CHARGE
PUMP
2 BIT
LATCH
17 BIT LATCH
DIVIDE RATIO
4 BIT
LATCH
DRIVE
DISABLE
C1, C0
PE
1 BIT
LATCH
CHARGE
PUMP
16
MODE
CONTROL
RF
INPUTS
Fcomp
PROGRAMMABLE
DIVIDER
5 BIT LATCH and
MODE CONTROL
LOGIC
(see Fig. 5)
ADDRESS
SDA
SCL
4
5
I 2C
TRANSCEIVER
6
FPD /2
FL
POWER ON
DETECT
ADC
11
15 V
EE
4 BIT
LATCH AND
PORT
INTERFACE
POR
P0 TEST
CONTROL
12 V
CC
3 BIT ADC
7
PORT P3
8
PORT P2
9
10
PORT P1 PORT P0
Fig. 2 Block diagram
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
Supply current, I CC
12
Value
Min
RF input voltage
2
Units
Conditions
Typ
68
Max
85
mA
V CC = 5V prescaler enabled, PE = 1
58
mA
mV rms
V CC = 5V prescaler disabled, PE = 0
300MHz to 2.7GHz Prescaled
enabled, PE = 1, See Fig. 7b.
80MHz Prescaler enabled,
PE=1, See Fig. 7b.
13, 14
40
73
300
13, 14
100
300
mV rms
13,14
50
300
mV rms
RF input impedance
13, 14
50
Ω
80MHz to 2.0GHz Prescaler
disabled, PE = 0, See Fig. 7a.
Refer to Fig. 13
RF input capacitance
13, 14
2
pF
Refer to Fig. 13
SP5669
ELECTRICAL CHARACTERISTICS (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
Min
SDA, SCL
Input High voltage
Input Low voltage
Input High current
Input Low Current
LeakageCurrent
Input hysteresis
SDA Output voltage
Charge pump output current
Charge pump output leakage
Charge pump drive output
current
Drive output saturation
voltage when disabled
External reference input
frequency
External reference input
ampltude
Crystal frequency
Crystal oscillator drive level
Recommended crystal series
resistance
Crystal oscillator negative
resistance
REF/COMP output
Voltage
3
0
5.5
1.5
10
–10
10
Conditions
0.4
V
V
µA
µA
µA
V
V
± 10
nA
I sink = 3mA
See Fig. 6, V pin = 2V
V pin1 = 2V
mA
V pin16 = 0.7V
0.8
5
1
1
16
±3
1
16
350
mV
Input voltage = V CC
Input voltage = VEE
VCC = VEE
2
2
20
MHz
AC coupled sinewave
2
2
2
200
4
500
16
mV p–p
MHz
mV p–p
AC coupled sinewave
200
Ω
Applies to 4MHz crystal only.
‘Parallel resonant’ crystal. Figure
quoted is under all conditions
including start up.
Ω
Includes temperature and
process tolerances.
mV p–p
AC coupled output. Output
enabled,RE=1. See Note 1.
35
10
2
400
3
350
2
–148
RF division ratio
Sink current
Leakage current
ADC input voltage
ADC input current
Address input current High
Address input current Low
Units
Max
5, 6
Comparison frequency
Equivalent phase noise at
phase detector
Reference division ratio
Output ports P0, P1, P2, P3
Value
Typ
240
480
MHz
dBC/Hz
131071
262142
6kHz loop BW, phase comparator
freq 250kHz. Figure measured @
1kHz offset, SSB (within loop
band width).
Prescaler disabled, PE = 0
Prescaler enabled, PE = 1
See Fig. 3
7,8,9,
10
10
11
11
4
4
10
mA
µA
±10
1
–0.5
µA
mA
mA
V port = 0.7V
V port = 13.2V
See Table 4, Fig 4
VCC ≥ V input ≥ VEE
Input voltage =V CC
Input voltage =VEE
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.
3
SP5669
ABSOLUTE MAXIMUM RATINGS
All voltages are referred to VEE at 0V.
Characteristics
Pin
Value
Max
Supply Voltage, V CC
RF input voltage
12
13,14
0.3
7
2.5
V
V p–p
RF input DC offset
Port voltage
13,14
7–10
–0.3
–0.3
V CC +0.3
14
V
V
–0.3
Total port current
7–10
7–10
6
50
V
mA
ADC input DC offset
REF/COMP output DC offset
11
3
–0.3
–0.3
V CC +0.3
V CC +0.3
V
V
Charge pump DC offset
Drive DC offset
1
16
–0.3
–0.3
V CC +0.3
V CC +0.3
V
V
Crystal oscillator DC offset
Address DC offset
2
4
–0.3
–0.3
V CC +0.3
V CC +0.3
V
V
5, 6
–0.3
–55
6V
+150
V
°C
+150
°C
chip to ambient
chip to case
111
41
°C/W
°C/W
Power consumption at V CC =5.5V
ESD protection
468
mW
kV
SDA and SCL DC offset
Storage temperature
Junction temperature
MP16 thermal resistance
All
4
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 high
4
Units
Min
Conditions
AC coupled as per application
Port in off state
Port in on state
All ports off, prescaler enabled
Mil Std 883 TM 3015
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
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
SP5669
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.
To facilitate smooth fine tuning, the frequency data bytes
are only accepted by the device after all 17 bits of frequency
data have been received, or after the generation of a STOP
condition. Repeatedly sending bytes 2 and 3 only will not
change the frequency. A frequency change occurs when one
of the following data sequences is sent to an addressed
device;
Bytes 2, 3, 4, 5
Bytes 4, 5, 2, 3
or when a STOP condition follows valid data bytes as
follows;
Bytes 2, 3, 4, STOP
Bytes 4, 5, 2 STOP
Bytes 2, 3, STOP
Bytes 2, STOP
Bytes 4, STOP
It should be noted that the device must be initially addressed
with both frequency AND control byte data, since the control
byte contains reference divider information which must be
provided before a chosen frequency can be synthesised. This
implies that after initial turn on, bytes 2, 3, 4 must be sent
followed by a STOP condition as a minimum requirement.
Alternatively bytes 2, 3, 4, 5 must be sent if port information is
also required.
READ MODE
When the device is in read mode, the status byte read from
the device takes the form shown in Table 2, Fig. 4.
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 (at low VCC), the
programmed information is lost and the output ports are all set
to high impedance.
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 the
device is unlocked.
Bits 6,7 and 8 (A2, A1, A0) combine to give the output of the
ADC. The ADC can be used to feed AFC information to the
microprocessor via the I 2 C bus.
ADDITIONAL PROGRAMMABLE FEATURES
Prescaler enable
The divide by two prescaler is enabled by setting bit PE within
byte 4 to a logic ’1’. A logic ’0’ disables the prescaler, directly
passing the RF input frequency to the 17–bit programmable
counter. Bit PE is a static select only.
Charge pump current
The charge pump current can be programmed by bits C1 and
C0 within data byte 5, as defined in Fig. 6.
Test mode
The test modes are invoked by setting bits RE=0 and RTS=1
within the programming data, and are selected by bits TS2,
TS1 and TS0 as shown in Fig. 5. When TS2, TS1 and TS0 are
received, the device retains previously received P2, P1 and
P0 data.
Reference/Comparison frequency output
The reference frequency F ref can be switched to the REF/
COMP output, pin 3, by setting bit RE=1 and RTS=0 within
byte 5. The comparison frequency F comp can be switched to
the REF/COMP output, pin 3, by setting bit RE=1 and RTS=1
within byte 5. For RE set to logic ’0’, the output is disabled and
set to a high state. RE and RTS default to logic ’1’ during
device power up, thus enabling the comparison frequency F
comp at the REF/COMP output.
Comparison
frequency with a
4MHz external
reference
R3
R2
R1
R0
Ratio
0
0
0
0
0
0
0
1
2
4
2MHz
1MHz
0
0
0
0
1
1
0
1
8
16
500kHz
250kHz
0
0
1
1
0
0
0
1
32
64
125kHz
62.5kHz
0
0
1
1
0
1
0
1
128
256
31.25kHz
15.625kHz
1
0
0
0
Not
Allowed
-
1
1
0
0
0
1
1
0
6
12
666.67kHz
333.33kHz
1
1
0
1
1
0
1
0
24
48
166.67kHz
83.33kHz
1
1
1
1
0
1
1
0
96
192
41.67kHz
20.83kHz
1
1
1
1
384
10.42kHz
Fig. 3 Reference division ratios
5
SP5669
ADDRESS
PROGRAMMABLE
DIVIDER
PROGRAMMABLE
DIVIDER
CONTROL DATA
CONTROL DATA
MSB
1
1
0
0
0
MA1
MA0
LSB
0
A
Byte 1
0
2 14
2 13
2 12
2 11
210
29
28
A
Byte 2
27
26
25
24
23
22
21
20
A
Byte 3
1
C1
16
15
PE
RTS
R3
P3
A
A
Byte 4
Byte 5
A
A
Byte 1
Byte 2
2
RE
2
C0
R2
R1
R0
P2/TS2 P1/TS1 P0/TS0
Table 1 Write data format (MSB is transmitted first)
MSB
ADDRESS
STATUS BYTE
1
POR
LSB
1
FL
0
X
0
X
0
X
MA1
A2
MA0
A1
1
A0
Table 2 Read data format (MSB is transmitted first)
A
MA1, MA0
2 16 –2 0
PE
R3,R2,R1,R0
C1, C0
RE
RTS
RTS
TS2, TS1, TS0
P0
P3, P2, P1
POR
FL
A2, A1, A0
X
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
:
Acknowledge bit
Variable address bits (see Table 3)
Programmable division ratio control bits
Prescaler enable
Reference division ratio select (see Fig. 3)
Charge pump current select (see Fig.6)
Reference oscillator output enable
REF/COMP output select when RE=1 (see Fig.5)
Test mode enable when RE=0 (see Fig.5)
Test mode control bits (valid when RE=0, RTS=1, see Fig. 5)
P0 port output state (always valid except when RE=0, RTS=1)
P3, P2 and P1 port output states
Power On Reset indicator
Phase Lock Flag
ADC data (see Table 4)
Don’t care
MA1
MA0
Address input voltage level
A2
A1
A0
Voltage on ADC input
0
0
0
1
0 – 0.1VCC
Open circuit
1
0
0
1
0
1
0.6V CC toV CC
0.45V CC to 0.6VCC
1
1
0
1
0.4V CC – 0.6VCC #
0.9V CC – VCC
0
0
1
0
0
1
0.3V CC to 0.45VCC
0.15V CC to 0.3VCC
0
0
0
0 to 0.15VCC
# Programmed by connecting a 15kΩ resistor between
pin 4 and VCC
Table 3 Address selection
Fig. 4 Data formats
6
Table 4 ADC levels
SP5669
RE
RTS
TS2
TS1
TS0
REF/COMP OUTPUT
MODE
Test mode description
0
0
0
1
X
X
X
0
X
0
Disabled to high state
Disabled to high state
Normal operation
Charge pump sink.
Status byte FL = logic ‘1’
0
1
X
0
1
Disabled to high state
Charge pump source.
Status byte FL = logic ‘0’
0
1
X
1
0
Disabled to high state
Charge pump disabled.
Status byte FL=logic ‘0’
0
0
1
1
X
1
1
X
1
X
Disabled to high state
Disabled to high state
Port P0 = F pd /2
Varactor Drive Output
1
0
X
X
X
F ref switched
disabled
Normal operation
1
1
X
X
X
F comp switched
Normal operation
X=don’t care
Fig. 5 REF/COMP output mode and Test modes
C1
byte 5, bit 1
Current in µA
C0
byte 5, bit 2
min
typ
max
0
0
0
1
±90
±195
±120
±260
±150
±325
1
1
0
1
±416
±900
±555
±1200
±694
±1500
Fig 6. Charge pump current
300
VIN
(mV RMS
INTO 50 )
300
VIN
(mV RMS
INTO 50 )
OPERATING
WINDOW
100
50
50
10
10
80 100
1000
OPERATING
WINDOW
100
2000
3000 3500
FREQUENCY (MHz)
Fig. 7a Typical input sensitivity (prescaler disabled, PE=0)
80 300
1000
2000
3000 3500
2700
FREQUENCY (MHz)
Fig. 7b Typical input sensitivity (prescaler disabled, PE=1)
7
SP5669
DOUBLE CONVERSION TUNER SYSTEMS
the SP5669 to be used both for the up converter LO with a high
phase comparator frequency (hence low phase noise) and the
down converter which utilises the device in a lower
comparison frequency mode (which offers a fine step size).
The high 2.7GHz maximum operating frequency and
excellent noise characteristics of the SP5669 enables the
construction of double conversion high IF tuners.
A typical system shown in Fig.8 will use the SP5669 as the
first LO control for full band upconversion to an IF of greater
than 1GHz. The wide range of reference division ratios allows
1.6GHz
50–900MHz
38.9MHz
1650–2700MHz
Reference Clock
First LO
Second LO
SP5659
SP5669
SP5659
SP5669
Fig. 8 Example of double conversion from VHF/UHF frequencies to TV IF
+30V
68pF
4MHz 18pF
15nF
+5V
22k
16k
13k3
BCW31
REF 10n
CONTROL
MICRO
ADDRESS
SDA
1
16
2
15
3
14
4
5
SCL
6
SP5669
SP5659
Optional application utilising
on–board crystal controlled
oscillator
+12V
47k
2n2
TUNER
1n
1n
OSCILLATOR
OUTPUT
13
12
11
P3
7
10
ADC
P0
P2
8
9
P1
10n
Fig. 9 Typical appliction
APPLICATION NOTES
A generic set of application notes AN168 for designing with
synthesisers such as the SP5659 has been written. This
covers aspects such as loop filter design and decoupling. This
application note is also featured in the Media Data Book, or
refer to the Mitel Semicondor Internet Site http://
www.gpsemi.com. A generic test/demo board has been produced which can be used for the SP5669. A circuit diagram
and list of components for the board is shown in Figs. 10 and
11.
8
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
SP5669
P2 +30V
+5V
+12V
C8
C9
C7/C8/C9 = 100nF
EXTERNAL REFERENCE
SKT2
C6
10nF*
*(NOT FITTED)
C3
68pF
C2
15nF
R6 13K3
1
16
2
15
3
14
ENABLE
4
13
DATA / SDA
5
12
CLOCK / SCL
6
11
7
10
8
9
X1 4MHz C1
R8
R9
16K
47K
C12
2n2F
T1
2N3904
VAR
GND
RF INPUT
C4
C5
1nF
1nF
SKT1
C10
1nF
R5 4K7
R4 4K7
R3 4K7
C14
100pF
R2 4K7
C13
100pF
C7
18pF
R1 4K7
P1
DISABLE / REF
R7
22K
D1 D2 D3 D4
D5
LOCK
C11
1nF
NOTE : The circuit diagram shown is designed
for use with a number of synthesisers.
. is redundant when
The LED connected to pin 11
a SP5669
SP5659 is used in this board.
Fig. 10 Test board
Fig. 11 Test board (layout)
9
SP5669
LOOP BANDWIDTH
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:–
The majority of applications for which the SP5669 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.
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.
REFERENCE SOURCE
The SP5669 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:
(
DRIVING TWO DEVICES FROM A COMMON
REFERENCE
)
phase comparator
LO frequency
noise floor + 20 log 10 phase comparator frequency
As mentioned earlier in the Datasheet, the SP5669 has a
REF/COMP output which allows two synthesisers to be driven
from a common reference. To do this, the ‘‘Master” should be
programmed by setting RE = 1 and RTS = 0. The driven device
should be programmed for normal operation i.e. RE = 0, and
RTS = 0. The two devices should be connected as shown
below.
Assuming the phase comparator noise floor is flat
irrespective of sampling frequency, this means that the best
16
1
16
2
15
2
15
3
14
3
14
13
4
12
5
4
5
6
1nF
SP5669
SP5659
1
SP5669
SP5659
4MHz 18pF
13
12
11
6
11
7
10
7
10
8
9
8
9
Fig. 12 Driving two devices from a common reference
+j1
+j0.5
+j2
+j0.2
0
+j5
0.2
0.5
1
2
5
X
X
–j0.2
–j5
X
S11:Z0 = 50
–j0.5
X
NORMALISED TO 50
–j2
–j1
Fig. 13 typical RF input impedance
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FREQUENCY MARKERS AT 100MHz,
500MHz, 1GHz AND 2.7GHz
SP5669
VREF
VCC
500
500
CHARGE
PUMP
RF INPUTS
200
DRIVE
OUTPUT
100
OS
(Output disable)
RF inputs
Loop amplifier
V CC
PORT
SCL/SDA/ADC
3k
ACK
SDA ONLY
Output Ports
SDA and SCL and ADC
VCC
VCC
VCC
30k
REF/COMP
ADDRESS
3k
CRYSTAL
enable/
disable
10K
Reference oscillator
Address input
REF/COMP output
Fig. 14 Input/Output interface circuits
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SP5669
PACKAGE DETAILS
Dimensions are shown thus: mm (in). For further package information, please contact your local Customer Service Centre.
9·80/10·01
(0·386/0·394)
16
SPOT REF.
0·18/0·25
(0·007/0·010)
0·25/0·51
(0·010/0·020)
5·80/6·20
3·80/4·00
×45°
(0·150/0·157) (0·228/0·244)
CHAMFER
REF.
PIN 1
0-8°
0·35/0·49
(0·014/0·019)
0·41/1·27
(0·016/0·050)
0·69 (0·027)
MAX
16 LEADS AT
1·27 (0·050)
NOM SPACING
0·10/0·25
1·35/1·91
(0·004/0·010) (0·053/0·075)
NOTES
1. Controlling dimensions are inches.
2. This package outline diagram is for guidance
only. Please contact your Mitel Semiconductor
Customer Service Centre for further
16-LEAD MINIATURE PLASTIC DIL - MP16
Purchase of Mitel Semiconductor I2C components conveys a licence under the Philips I2C Patent rights to use these components in an I2C System, provided that the system conforms to the I2C Standard Specification as defined by Philips.
HEADQUARTERS OPERATIONS
MITEL SEMICONDUCTOR
Cheney Manor, Swindon,
Wiltshire SN2 2QW, United Kingdom.
Tel: (01793) 518000
Fax: (01793) 518411
MITEL SEMICONDUCTOR
1500 Green Hills Road,
Scotts Valley, California 95066-4922
United States of America.
Tel (408) 438 2900
Fax: (408) 438 5576/6231
Internet: http://www.gpsemi.com
CUSTOMER SERVICE CENTRES
● FRANCE & BENELUX Les Ulis Cedex Tel: (1) 69 18 90 00 Fax : (1) 64 46 06 07
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● JAPAN Tokyo Tel: (03) 5276-5501 Fax: (03) 5276-5510
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● NORTH AMERICA Scotts Valley, USA Tel: (408) 438 2900 Fax: (408) 438 5576/6231
● SOUTH EAST ASIA Singapore Tel:(65) 3827708 Fax: (65) 3828872
● SWEDEN Stockholm Tel: 46 8 702 97 70 Fax: 46 8 640 47 36
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● UK, EIRE, DENMARK, FINLAND & NORWAY
Swindon Tel: (01793) 726666 Fax : (01793) 518582
These are supported by Agents and Distributors in major countries world-wide.
© Mitel Corporation 1998 Publication No. DS4852 Issue No. 1.3 November 1997
TECHNICAL DOCUMENTATION – NOT FOR RESALE. PRINTED IN UNITED KINGDOM
This publication is issued to provide information only which (unless agreed by the Company in writing) may not be used, applied or reproduced for any purpose nor form part of any order or contract nor to be regarded
as a representation relating to the products or services concerned. No warranty or guarantee express or implied is made regarding the capability, performance or suitability of any product or service. The Company
reserves the right to alter without prior notice the specification, design or price of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute any
guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user's responsibility to fully determine the performance and suitability of any equipment using such information and
to ensure that any publication or data used is up to date and has not been superseded. These products are not suitable for use in any medical products whose failure to perform may result in significant injury
or death to the user. All products and materials are sold and services provided subject to the Company's conditions of sale, which are available on request.
All brand names and product names used in this publication are trademarks, registered trademarks or trade names of their respective owners.
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