ZARLINK NJ8821

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RECOMMENDED FOR NEW DESIGNS
NJ8821
DS3278-1.3
NJ8821
FREQUENCY SYNTHESISER (MICROPROCESSOR INTERFACE)
WITH RESETTABLE COUNTERS
The NJ8821 is a synthesiser circuit fabricated on the GPS
CMOS process and is capable of achieving high sideband
attenuation and low noise performance. It contains a reference
oscillator, 11-bit programmable reference divider, digital and
sample-and-hold comparators, 10-bit programmable ‘M’ counter,
7-bit programmable ‘A’ counter and the necessary control and
latch circuitry for accepting and latching the input data.
Data is presented as eight 4-bit words under external control
from a suitable microprocessor..
It is intended to be used in conjunction with a two-modulus
prescaler such as the SP8710 series to produce a universal
binary coded synthesiser.
The NJ8821 is available in Plastic DIL (DP) and Miniature
Plastic DIL (MP) packages, both with operating temperature
range of 230°C to 170°C. The NJ8821MA is available only in
Ceramic DIL package with operating temperature range of
240°C to 185°C.
FEATURES
■
■
■
■
PDA
1
20
CH
PDB
2
19
RB
LD
3
18
MC
FIN
4
17
DS2
VSS
5
16
DS1
VDD
6
15
DS0
OSC IN
7
14
PE
OSC OUT
8
13
NC
D0
9
12
D3
D1
10
11
D2
NJ8821
DP20, MP20
DG20
Fig.1 Pin connections - top view
Low Power Consumption
Microprocessor Compatible
ABSOLUTE MAXIMUM RATINGS
High Performance Sample and Hold Phase Detector
Supply voltage, VDD2VSS
Input voltage
Open drain output, pin 3
All other pins
Storage temperature
>10MHz Input Frequency
ORDERING INFORMATION
NJ8821 BA DP Plastic DIL Package
NJ8821 BA MP Miniature Plastic DIL Package
NJ8821 MA DG Ceramic DIL Package
Storage temperature
DATA SELECT INPUTS
DS0 DS1 DS2
15
PROGRAM
ENABLE (PE)
OSC IN
OSC OUT
14
7
16
RB
17
FIN
VDD
LATCH SELECT
LOGIC
REFERENCE COUNTER
(11BITS)
42
fr
9
10
11
12
20
SAMPLE/HOLD
PHASE
DETECTOR
1
FREQUENCY/
PHASE
DETECTOR
2
3
LATCH 4 LATCH 5
LATCH 1 LATCH 2 LATCH 3
‘A’ COUNTER
(7 BITS)
‘M’ COUNTER
(10 BITS)
PDA
PDB
LOCK DETECT (LD)
VSS
fv
6
CONTROL LOGIC
VSS
CH
TO
INTERNAL
LATCHES
8
4
7V
VSS20·3V to VDD10·3V
265°C to 1150°C
(DG package, NJ8821MA)
255°C to 1125°C
(DP and MP packages, NJ8821)
19
LATCH 6 LATCH 7 LATCH 8
 D0
DATA
D1
INPUTS  D2
 D3
20·5V to 7V
5
Fig.2 Block diagram
18
MODULUS
CONTROL
OUTPUT (MC)
NJ8821
ELECTRICAL CHARACTERISTICS AT VDD = 5V
Test conditions unless otherwise stated:
VDD–VSS=5V ±0·5V. Temperature range NJ8821 BA: –30°C to +70°C; NJ8821MA: –40°C to +85°C
DC Characteristics
Min.
Supply current
OUTPUT LEVELS
Modulus Control Output (MC)
High level
Low level
Lock Detect Output (LD)
Low level
Open drain pull-up voltage
PDB Output
High level
Low level
3-state leakage current
INPUT LEVELS
Data Inputs (D0-D3)
High level
Low level
Program Enable Input (PE)
High level
Low level
Data Select Inputs (DS0-DS2)
High level
Low level
Units
Conditions
Typ.
Max.
3·5
0·7
5·5
1·5
mA
mA
0·4
V
V
ISOURCE = 1mA
ISINK = 1mA
0·4
7
V
V
ISINK = 4mA
0·4
±0·1
V
V
µA
ISOURCE = 5mA
ISINK = 5mA
0·4
V
V
TTL compatible
See note 1
0·75
V
V
0·75
V
V
4·6
4·6
4·25
4·25
4·25
fosc, fFIN = 10MHz
fosc, fFIN = 1·0MHz



Value
Characteristic
0 to 5V
square
wave
AC Characteristics
Value
Characteristic
Min.
Propagation delay, clock to MC
Strobe pulse width, tW(ST)
Data set-up time, tDS
Data hold time, tDH
Latch address set-up time, tSE
Latch address hold time, tHE
Digital phase detector propagation delay
Gain programming resistor, RB
Hold capacitor, CH
Output resistance, PDA
Digital phase detector gain
Units
200
10·6
30
Conditions
Max.
50
mVRMS 10MHz AC-coupled sinewave
MHz
Input squarewave VDD to VSS,
See note 4.
ns
See note 2.
µs
µs
See Fig. 6
µs
µs
µs
ns
See note 3.
kΩ
nF
kΩ
V/Rad





FIN and OSC IN input level
Max. operating frequency, fFIN and fosc
Typ.
2
1
1
1
1
500
5
1
5
0·4
NOTES
1. Data inputs have internal pull-up resistors to enable them to be driven from TTL outputs.
2. All counters have outputs directly synchronous with their respective clock rising edges.
3. The finite output resistance of the internal voltage follower and ‘on’ resistance of the sample switch driving this pin will add a finite time constant
to the loop. An external 1nF hold capacitor will give a maximum time constant of 5µs, typically.
4. Operation at up to 15MHz is possible with a full logic swing but is not guaranteed.
2
NJ8821
PIN DESCRIPTIONS
Pin no.
Name
Description
1
PDA
Analog output from the sample and hold phase comparator for use as a ‘fine’ error signal. Output at
(VDD2VSS)/2 when the system is in lock. Voltage increases as fv phase lead increases; voltage
decreases as fr phase lead increases. Output is linear over only a narrow phase window, determined
by gain (programmed by RB).
2
PDB
Three-state output from the phase/frequency detector for use as a ‘coarse’ error signal.
fv. fr or fv leading: positive pulses with respect to the bias point VBIAS
fv , fr or fr leading: negative pulses with respect to the bias point VBIAS
fv = fr and phase error within PDA window: high impedance.
3
LD
An open-drain lock detect output at low level when phase error is within PDA window (in lock); high
impedance at all other times.
4
FIN
The input to the main counters, normally driven from a prescaler, which may be AC-coupled or, when
a full logic swing is available, may be DC-coupled.
5
VSS
Negative supply (ground).
6
VDD
Positive supply.
OSC IN/ These pins form an on-chip reference oscillator when a series resonant crystal is connected across
OSC OUT them. Capacitors of appropriate value are also required between each end of the crystal and ground
to provide the necessary additional phase shift. An external reference signal may, alternatively, be
applied to OSC IN. This may be a low-level signal, AC-coupled, or if a full logic swing is available it may
be DC-coupled. The program range of the reference counter is 3 to 2047, with the division ratio being
twice the programmed number.
7, 8
9,10, 11, 12
D0-D3
13
NC
No connection
14
PE
This pin is used as a strobe for the data. A logic ‘1’ on this pin transfers data from the D0-D3 pins to
the internal latch addressed by the data select (DS0-DS2) pins . A logic ‘0’ disables the data inputs.
15, 16, 17
DS0-DS2
18
MC
Modulus control output for controlling an external dual-modulus prescaler. MC will be low at the beginning
of a count cycle and will remain low until the ‘A’ counter completes its cycle. MC then goes high and
remains high until the ‘M’ counter completes its cycle, at which point both ‘A’ and ‘M’ counters are reset.
This gives a total division ratio of MP1A, where P and P11 represent the dual-modulus prescaler
values. The program range of the ‘A’ counter is 0-127 and therefore can control prescalers with a
division ratio up to and including 4128/129. The programming range of the ‘M’ counter is 8-1023
and, for correct operation, M>A. Where every possible channel is required, the minimum total division
ratio should be P 22P.
19
RB
An external sample and hold phase comparator gain programming resistor should be connected
between this pin and VSS.
20
CH
An external hold capacitor should be connected between this pin and VSS.
Data on these inputs is transferred to the internal data latches during the appropriate data read time
slot. D3 is MSB, D0 is LSB.
Data select inputs for addressing the internal data latches
8
2·0
VDD = 5V
FIN = LOW FREQUENCY
0V TO 5V SQUARE WAVE
7
1·5
SUPPLY CURRENT (mA)
SUPPLY CURRENT (mA)
VDD = 5V
OSC IN, FIN = 0V TO 5V SQUARE WAVE
OSC IN
1·0
FIN
6
5
10MHz
4
1MHz
3
2
0·5
TOTAL SUPPLY CURRENT IS
THE SUM OF THAT DUE TO FIN
AND OSC IN
1
2
3
4
5
6
7
INPUT FREQUENCY (MHz)
8
Fig. 3 Typical supply current v. input frequency
9
1
10
0·2
0·4
0·6
0·8
1·0
1·2
INPUT LEVEL (V RMS)
1·4
1·6
Fig. 4 Typical supply current v. input level, OSC IN
3
NJ8821
PROGRAMMING
Timing is generated externally, normally from a
microprocessor, and allows the user to change the data in
selected latches as defined by the data map Fig.5. The PE pin
is used as a strobe for the data: taking PE high causes data to
be transferred from the data pins (D0-D3) into the addressed
latch. Following the falling edge of PE, the data is retained in
the addressed latch and the data inputs are disabled. Data
transfer from all internal latches into the counters occurs
simultaneously with the transfer of data into latch 1, which
would therefore normally be the last latch addressed during
each channel change. Timing information for this mode of
operation is given in Fig. 6.
When re-programming, a reset to zero state is followed by
reloading with the new counter values. This means that the
synthesiser loop lock-up time is well defined and less than
10ms. If shorter lock-up times are are required when making
only small changes in frequency, the GPS NJ8823 (with nonresettable counters) should be considered.
WORD DS2
1
2
3
4
5
6
7
8
0
0
0
0
1
1
1
1
DS1
DS0
D3
D2
D1
D0
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
M1
M5
M9
A3
R3
R7
-
M0
M4
M8
A2
A6
R2
R6
R10
M3
M7
A1
A5
R1
R5
R9
M2
M6
A0
A4
R0
R4
R8
Fig. 5 Data map
DS0-DS2
PE
D0 - D3
tDS
tSE
tDH
tW(ST)
tHE
Fig. 6 Timing diagram
PHASE COMPARATORS
The digital phase/frequency detector drives a three-state
output, PDB, which provides a ‘coarse’ error signal to enable
fast switching between channels. The PDB output is active
until the phase error is within the sample and hold phase
detector, PDA, window, when PDB becomes high impedance.
Phase-lock is indicated at this point by a low level on LD. The
sample and hold phase detector provides a ‘fine’ error signal
to give further phase adjustment and to hold the loop in lock.
An internally generated ramp, controlled by the digital
output from both the reference and main divider chains, is
sampled at the reference frequency to give the ‘fine’ error
signal, PDA. When in phase lock, this output would be typically
at (VDD2VSS)/2 and any offset from this would be proportional
to phase error. The relationship between this offset and the
4
phase error is the phase comparator gain, which is
programmable with an external resistor, RB. An internal 50pF
capacitor is used in the sample and hold comparator.
CRYSTAL OSCILLATOR
When using the internal oscillator, the stability may be
enhanced at high frequencies by the inclusion of a resistor
between pin 8 (OSC OUT) and the other components. A value
of 150-270Ω is advised.
PROGRAMMING/POWER UP
Data and signal input pins should not have input applied to
them prior to the application of VDD, as otherwise latch-up may
occur.
NJ8821
HEADQUARTERS OPERATIONS
GEC PLESSEY SEMICONDUCTORS
Cheney Manor, Swindon,
Wiltshire SN2 2QW, United Kingdom.
Tel: (0793) 518000
Fax: (0793) 518411
GEC PLESSEY SEMICONDUCTORS
P.O. Box 660017
1500 Green Hills Road,
Scotts Valley, California 95067-0017,
United States of America.
Tel: (408) 438 2900
Fax: (408) 438 5576
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 GEC Plessey Semiconductors 1992
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