SONY CXA3266Q

CXA3266Q
PLL IC for LCD Monitor/Projector
Description
The CXA3266Q is a PLL IC for LCD monitors/
projectors with built-in phase detector, charge pump,
VCO and counter.
The various internal settings are performed by
serial data via a 3-line bus.
Applicable LCD monitor/projector resolution are
NTSC, PAL, VGA, SVGA, XGA, SXGA and UXGA
etc.
The CXA3266Q is the same package as the
previous CXA3106Q and CXA3106AQ. They have
the same pin configuration excluding Pin 38.
Functions
• Phase detector enable
• UNLOCK output
• Output TTL disable function
• Power saving function (2 steps)
TTLGND
TTLVCC
PECLVCC
IOGND
CLK/2L
CLK/2H
CLKL
CLKH
DSYNCL
Applications
• CRT displays
• LCD projectors
• LCD monitors
• Multi-media
• Digital TV
DSYNCH
Pin Configuration (Top View)
VBB
PECLVCC
Features
• Supply voltage: 5 ± 0.25V single power supply
• Package: 48-pin QFP
• Power consumption: 328mW
• Sync input frequency: 10 to 120kHz
• Clock output signal frequency: 10 to 203MHz
• Clock delay: 8/32 to 48/32 CLK
• Sync delay: 8/32 to 48/32 CLK
• I/O level: TTL, PECL (complementary)
• Low clock jitter
• 1/2 clock output
• TTL output high level control function
48 pin QFP (Plastic)
36 35 34 33 32 31 30 29 28 27 26 25
IOGND 37
24 DSYNC
VOCLP 38
23 CLK
PLLVCC 39
22 CLKN
PLLGND 40
21 CLK/2
VCOVCC 41
20 CLK/2N
VCOGND 42
19 DGND
18 DVCC
VCOHGND 43
17 UNLOCK
IREF 44
RC2 45
16 DIVOUT
RC1 46
15 SEROUT
14 CS
IRGND 47
13 TLOAD
4
5
6
7
8
9 10 11 12
IOVCC
VCOH
VCOL
VCO
HOLD
SYNCH
SYNCL
SYNC
SCLK
3
SDATA
2
SENABLE
1
IOGND
IRVCC 48
Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by
any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the
operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits.
–1–
E99426-PS
CXA3266Q
Absolute Maximum Ratings (Ta = 25°C)
• Supply voltage
•
•
•
•
IOVCC, DVCC, TTLVCC, PECLVCC, PLLVCC,
VCOVCC, IRVCC,
–0.5 to +7.0
V
IOGND, DGND, TTLGND, VCOHGND, PLLGND,
VCOGND, IRGND
–0.5 to +0.5
V
Input voltage
VCOH, VCOL, SYNCH, SYNCL, VCO, HOLD,
SYNC, SENABLE, SCLK, SDATA, TLOAD, CS, VOCLP IOGND – 0.5 to IOVCC + 0.5 V
RC2
IRGND – 0.5 to IRVCC + 0.5 V
Output current
SEROUT, DIVOUT, UNLOCK, CLK/2N, CLK/2,
CLKN, CLK, DSYNC, CLK/2L, CLK/2H, CLKL,
CLKH, DSYNCH, DSYNCL, VBB
–30 to +30
mA
IREF, RC1
–2 to +2
mA
Storage temperature Tstg
–65 to +150
°C
Allowable power dissipation
PD
860
mW
Recommended Operating Conditions
IOVCC, DVCC, TTLVCC, PECLVCC,
PLLVCC, VCOVCC, IRVCC
IOGND, DGND, TTLGND, VCOHGND,
PLLGND, VCOGND, IRGND
• Digital input
DIN (PECL) ∗1 H level
DIN (PECL) ∗1 L level
DIN (TTL) ∗2 H level
DIN (TTL) ∗2 L level
VOCLP (clamp voltage)
• SYNC, SYNCH, SYNCL input jitter
• Operating ambient temperature
Ta
Min.
Typ.
Max.
4.75
5.00
5.25
V
–0.05
IOVCC – 1.1
0
0.05
V
IOVCC – 1.5
V
V
V
V
ns
• Supply voltage
∗1 VCOH, VCOL, SYNCH, SYNCL
∗2 VCO, HOLD, SYNC, SENABLE, SCLK, SDATA, TLOAD, CS
–2–
2.0
TTLGND + 2.4
0.8
TTLVCC
–20
+75
°C
TTLIN
PECLIN
SYNC
(TTL)
SYNC
(PECL)
–3–
IREF
DAC
TTLIN
PECLIN
VCO
(PECL)
HOLD
(TTL)
TTLIN
VCO
(TTL)
Block Diagram
SENABLE SCLK
logic
Latch
SEROUT
1bit
DIVOUT
TTLOUT
on/off
12bit
Programmable
Counter
TLOAD
TTLIN
1bit
SW
1bit
synthesizer
power save
2bit
DIV
1, 2, 4, 8
Delay
1bit
MUX
Coarse
Delay
1bit
1 to 2 CLK
2bit
2 to 5 CLK
Coarse
Delay
VCO
1/256 to 1/4096
6bit
Fine
Delay
1/32 to 64/32 CLK
2bit
DIV
pulse width
RC2
2bit
Charge
Pump
1bit
on/off
read out
TTLOUT
Phase
Detector
1bit
SDATA
CONTROL REGISTER
1bit
Polarity
RC1
CS
whole chip
power save
1/2
RSET
1bit
DSYNC
Hold
1bit
Polarity
1bit
1bit
1bit
1bit
1bit
PECL
on/off 1bit
unlock
detect
PECLOUT
TTLOUT
on/off
TTLOUT
on/off
PECLOUT
TTLOUT
on/off
TTLOUT
on/off
PECLOUT
TTLOUT
on/off
VOCLP
VBB
UNLOCK
CLK/2
(PECL)
NCLK/2
(TTL)
CLK/2
(TTL)
CLK
(PECL)
NCLK
(TTL)
CLK
(TTL)
DSYNC
(PECL)
DSYNC
(TTL)
CXA3266Q
CXA3266Q
Pin No.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
Symbol
IOVCC
IOGND
VCOH
VCOL
VCO
HOLD
SYNCH
SYNCL
SYNC
SENABLE
SCLK
SDATA
TLOAD
CS
SEROUT
DIVOUT
UNLOCK
DVCC
DGND
CLK/2N
CLK/2
CLKN
CLK
DSYNC
TTLGND
TTLVCC
IOGND
PECLVCC
CLK/2L
CLK/2H
CLKL
CLKH
DSYNCL
DSYNCH
VBB
PECLVCC
IOGND
VOCLP
PLLVCC
PLLGND
VCOVCC
VCOGND
VCOHGND
IREF
RC2
RC1
IRGND
IRVCC
Description
Digital power supply
Digital GND
External VCO input
External inverted VCO input
External VCO input
Phase detector disable signal input
Sync input
Inverted sync input
Sync input
Control signal (enable)
Control signal (clock)
Control signal (data)
Programmable counter test input
Chip select
Register read output
Programmable counter test output
Unlock signal output
Digital power supply
Digital GND
Inverted 1/2 clock output
1/2 clock output
Inverted clock output
Clock output
Delay sync signal output
TTL output GND
TTL output power supply
Digital GND
PECL output power supply
Inverted 1/2 clock output
1/2 clock output
Inverted clock output
Clock output
Delay sync signal output
Inverted delay sync signal output
PECL reference voltage
PECL output power supply
Digital GND
TTL high level clamp
PLL circuit analog power supply
PLL circuit analog GND
VCO circuit analog power supply
VCO circuit analog GND
VCO SUB analog GND
Charge pump current preparation
External pin for LPF
External pin for LPF
IREF analog GND
IREF analog power supply
–4–
Reference voltage level
5V
0V
PECL
PECL
TTL
TTL
PECL
PECL
TTL
TTL
TTL
TTL
TTL
TTL
TTL
TTL
TTL
5V
0V
TTL
TTL
TTL
TTL
TTL
0V
5V
0V
5V
PECL
PECL
PECL
PECL
PECL
PECL
PECLVCC – 1.7V
5V
0V
Clamp voltage
5V
0V
5V
0V
0V
1.2V
2.0 to 4.4V
2.1V
0V
5V
CXA3266Q
Pin Description and I/O Pin Equivalent Circuit
Pin
No.
Symbol
I/O
Reference
voltage level
Equivalent circuit
Description
1
IOVCC
—
5V
Digital power supply.
Ground this pin to the ground pattern
with a 0.1µF ceramic chip capacitor as
close to the pin as possible.
2
IOGND
—
0V
Digital GND.
18
DVCC
—
5V
Digital power supply.
19
DGND
—
0V
Digital GND.
25
TTLGND
—
0V
TTL output GND.
26
TTLVCC
—
5V
TTL output power supply.
Ground this pin to the ground pattern
with a 0.1µF ceramic chip capacitor as
close to the pin as possible.
27
IOGND
—
0V
Digital GND.
5V
PECL output power supply.
Ground this pin to the ground pattern
with a 0.1µF ceramic chip capacitor as
close to the pin as possible.
28
PECLVCC
—
36
PECLVCC
—
5V
PECL output power supply.
Ground this pin to the ground pattern
with a 0.1µF ceramic chip capacitor as
close to the pin as possible.
37
IOGND
—
0V
Digital GND.
39
PLLVCC
—
5V
PLL circuit analog power supply.
Ground this pin to the ground pattern
with a 0.1µF ceramic chip capacitor as
close to the pin as possible.
40
PLLGND
—
0V
PLL circuit analog GND.
41
VCOVCC
—
5V
VCO circuit analog power supply.
Ground this pin to the ground pattern
with a 0.1µF ceramic chip capacitor as
close to the pin as possible.
42
VCOGND
—
0V
VCO circuit analog GND.
43
VCOHGND —
0V
VCO SUB analog GND.
47
IRGND
0V
IREF analog GND.
5V
IREF analog power supply.
Ground this pin to the ground pattern
with a 0.1µF ceramic chip capacitor as
close to the pin as possible.
48
IRVCC
—
—
–5–
CXA3266Q
Pin
No.
3
Symbol
VCOH
I/O
I
Reference
voltage level
Equivalent circuit
PECL
External VCO input.
Programmable counter test input
(switchable by a control register).
When using the VCO PECL input,
open the Pin 5 VCO TTL input.
PECL
External inverted VCO input.
When open, this pin goes to the PECL
threshold voltage (IOVcc – 1.3V).
Only the Pin 3 VCOH input with VCOL
input open can be also operated but
complementary input is recommended
in order to realize stable high-speed
operation.
IOVCC
4
VCOL
I
14k
500
3
7
4
8
500
7
SYNCH
I
Description
PECL
14k
Sync input.
When using the SYNCH PECL input,
open the Pin 9 SYNC TTL input.
The sync signal can be switched
between positive/negative polarity by
an internal register.
IOGND
8
SYNCL
I
Inverted sync input.
When open, this pin goes to the PECL
threshold voltage (IOVcc – 1.3V).
Only the Pin 7 SYNCH input with
SYNCL input open can be also
operated but complementary
input is recommended in order to
realize stable high-speed operation.
PECL
–6–
CXA3266Q
Pin
No.
5
6
9
Symbol
VCO
HOLD
SYNC
I/O
I
I
I
Reference
voltage level
Equivalent circuit
Description
TTL
External VCO input.
Programmable counter test input
(controlled by a control register).
When using the VCO TTL input, open
the Pin 3 VCOH and Pin 4 VCOL
PECL inputs.
TTL
Phase detector disable signal.
Active high. When this pin is high, the
phase detector output is held. This pin
goes to high level when open.
(See the HOLD Timing Chart.)
Sync input.
When using the SYNC TTL input,
open the Pin 7 SYNCH and Pin 8
SYNCL PECL inputs.
The sync signal can be switched
between positive/negative polarity by
an internal register.
TTL
IOVCC
40k
5 10
10
SENABLE
I
TTL
192
6 11
9 12
1.5V
13
TTL
Control signal (clock) for setting the
internal registers.
When SENABLE is low, SDATA is
loaded to the registers at the rising
edge of SCLK.
When SENABLE is high, the register
contents are output from SEROUT at
the falling edge of SCLK.
(See the Control Register Table and
Control Timing Chart.)
TTL
Control signal (data) for setting the
internal registers.
(See the Control Register Table and
Control Timing Chart.)
TTL
Programmable counter test input.
This pin is normally open status and
high. Register contents can be loaded
immediately to programmable counter
by setting TLOAD low during the
programmable counter test mode.
IOGND
11
12
13
SCLK
SDATA
TLOAD
I
I
I
Control signal (enable) for setting the
internal registers.
When SENABLE is low, registers can
be written; when high, registers can be
read.
(See the Control Register Table and
Control Timing Chart.)
–7–
CXA3266Q
Pin
No.
Symbol
I/O
Reference
voltage level
Equivalent circuit
Description
IOVCC
40k
14
CS
I
TTL
Chip select.
When low, all circuits including the
register circuit are set to the power
saving mode.
When high, all circuits are set to
operating mode.
192
14
IOGND
TTLVCC
3k
38
VOCLP
I
Clamp
voltage
38
3.5k
TTLGND
–8–
TTL output high level clamp.
The TTL high level voltage is clamped
at the almost same value with the
voltage applied to this pin.
When this pin is open, TTL output
high level is approximately 2.7V by
dividing the internal resistor.
CXA3266Q
Pin
No.
15
16
20
Symbol
SEROUT
DIVOUT
CLK/2N
I/O
O
O
O
Reference
voltage level
Equivalent circuit
TTL
Register read output.
When SENABLE is high, the register
contents are output from SEROUT at
the falling edge of SCLK.
(See the Control Register Timing
Chart.)
TTL output can be turned ON/OFF
(high impedance) by a control register.
TTL
Programmable counter test output.
(See the I/O Timing Chart.)
TTL output can be turned ON/OFF
(high impedance) by a control register.
TTL
IOVCC
CLK/2
O
Inverted 1/2 clock output.
(See the I/O Timing Chart.)
TTL output can be turned ON/OFF
(high impedance) by a control register.
TTLVCC
100k
21
Description
TTL
15 22
16 23
20 24
21
TTLGND
TTL
Inverted clock output.
(See the I/O Timing Chart.)
TTL output can be turned ON/OFF
(high impedance) by a control register.
TTL
Clock output.
(See the I/O Timing Chart.)
TTL output can be turned ON/OFF
(high impedance) by a control register.
TTL
Delay sync signal output.
(See the I/O Timing Chart.)
TTL output can be turned ON/OFF
(high impedance) and switched
between positive/negative polarity by
a control register.
IOGND
22
23
24
CLKN
CLK
DSYNC
O
O
O
TTLVCC
17
UNLOCK
O
1/2 clock output.
(See the I/O Timing Chart.)
TTL output can be turned ON/OFF
(high impedance) by a control register.
TTL
17
TTLGND
IOGND
–9–
Unlock signal output.
This pin is an open collector output,
and pulls in the current when a phase
difference occurs. The UNLOCK
sensitivity can be adjusted by
connecting a capacitor and resistors
to this output appropriately.
(See the UNLOCK Timing Chart.)
TTL output can be turned ON/OFF
(high impedance) by a control register.
CXA3266Q
Pin
No.
29
30
Symbol
CLK/2L
CLK/2H
I/O
O
O
Reference
voltage level
Equivalent circuit
PECL
Inverted 1/2 clock output.
(See the I/O Timing Chart.)
This pin requires an external pulldown resistor.
When not used, connect to PECLVCC
without connecting a pull-down
resistor.
PECL
1/2 clock output.
(See the I/O Timing Chart.)
This pin requires an external pulldown resistor.
When not used, connect to PECLVCC
without connecting a pull-down
resistor.
IOVCC
31
CLKL
O
Description
PECLVCC
PECL
30 32 34
29 31 33
32
CLKH
O
PECL
IOGND
33
34
DSYNCL
DSYNCH
O
O
Inverted clock output.
(See the I/O Timing Chart.)
This pin requires an external pulldown resistor.
When not used, connect to PECLVCC
without connecting a pull-down
resistor.
Clock output.
(See the I/O Timing Chart.)
This pin requires an external pulldown resistor.
When not used, connect to PECLVCC
without connecting a pull-down
resistor.
PECL
Delay sync signal output.
(See the I/O Timing Chart.)
This pin requires an external pulldown resistor.
When not used, connect to PECLVCC
without connecting a pull-down
resistor.
PECL
Inverted delay sync signal output.
(See the I/O Timing Chart.)
This pin requires an external pulldown resistor.
When not used, connect to PECLVCC
without connecting a pull-down
resistor.
– 10 –
CXA3266Q
Pin
No.
Symbol
I/O
Reference
voltage level
Equivalent circuit
Description
PECLVCC
35
VBB
O
PECLVCC
–1.7V
35
PECL reference voltage.
When used, ground this pin to the
ground pattern with a 0.1µF ceramic
chip capacitor as close to the pin as
possible.
IOGND
IRVCC
44
IREF
—
Charge pump current preparation.
Connect to GND via an external
resistor (3.0kΩ).
Ground this pin to the ground pattern
with a 0.1µF ceramic chip capacitor
as close to the pin as possible.
1.2V
44
IRGND
IOGND
45
RC2
—
2.0
to
4.4V
IRVCC
46
45
IOGND
IRGND
46
RC1
—
2.1V
– 11 –
External pin for LPF.
See the Recommended Operating
Circuit for the external circuits. Note
that external resistors and capacitors
should be metal film resistors and
temperature compensation capacitors
which are relatively unaffected by
temperature change.
External pin for LPF.
See the Recommended Operating
Circuit for the external circuits.
– 12 –
Register 7
Register 6
Register 5
Register 4
Register 3
Register 2
Register 1
TESTPOWREG
register read no
TTLPOLREG
UNLOCK
Enable
DSYNC
Enable
DSYNC
Hold
37
NCLK/2
Enable
31
30
register read no
23
FINE
DELAY
Bit 5
17
VCO
DIV
Bit 5
3
DATA5
DSYNC
DELAY
29
COARSE COARSE
DELAY
DELAY
Bit 1
Bit 0
16
VCO
DIV
Bit 6
VCO
DIV
Bit 7
15
2
DATA6
1
DATA7
MSB
CPREG
register read no
DELAYREG
register read no
CENFREREG
register read no
DIVREG2
register read no
DIVREG1
register read no
Register No. Register Name
Control Register Table
DSYNC
By-pass
38
CLK/2
Enable
32
DIVOUT
Enable
39
NCLK
Enable
33
Read out
power
40
CLK
Enable
34
PD
POL
DSYNC
WIDTH
Bit 0
DSYNC
WIDTH
Bit 1
Synth
power
41
DSYNC
POL
35
C.Pump
Bit 1
27
VCO
By-pass
42
SYNC
POL
36
C.Pump
Bit 0
28
FINE
DELAY
Bit 0
FINE
DELAY
Bit 1
FINE
DELAY
Bit 2
26
22
21
20
25
FINE
DELAY
Bit 3
19
DIV 1, 2, 4, 8 DIV 1, 2, 4, 8
Bit 1
Bit 0
14
VCO
DIV
Bit 8
VCO
DIV
Bit 9
VCO
DIV
Bit 10
VCO
DIV
Bit 11
13
12
VCO
DIV
Bit 0
VCO
DIV
Bit 1
11
8
DATA0
LSB
7
DATA1
10
VCO
DIV
Bit 2
6
DATA2
9
VCO
DIV
Bit 3
5
DATA3
24
FINE
DELAY
Bit 4
18
VCO
DIV
Bit 4
4
DATA4
DATA
1
1
1
1
0
0
0
ADDR2
MSB
1
1
0
0
1
1
0
ADDR1
ADDRESS
1
0
1
0
1
0
1
ADDR0
LSB
CXA3266Q
CXA3266Q
Electrical Characteristics
Item
(Ta = 25°C, VCC = 5V, GND = 0V)
Symbol
Conditions
Min.
Typ.
Max.
Unit
Current consumption (excluding output current)
Current consumption 1
ICC1
CS = H, Synth Power = 1
51.0
65.5
79.0
mA
Current consumption 2
ICC2
CS = H, Synth Power = 0
9.0
13.0
16.0
mA
Current consumption 3
ICC3
CS = L
1.2
1.5
1.8
mA
Digital input
IOVCC
–1.15
Digital high level input
voltage (PECL)
VIH1
Digital low level input
voltage (PECL)
VIL1
VCOL, SYNCL input open
voltage (PECL)
VIO
Digital high level input
current (PECL)
IIH1
VIH = IOVCC – 0.8V
–100
100
µA
Digital low level input
current (PECL)
IIL1
VIL = IOVCC – 1.6V
–200
0
µA
Digital high level input
voltage (TTL)
VIH2
Digital low level input
voltage (TTL)
VIL2
Digital high level input
current (TTL)
IIH2
VIH = 3.5V
Digital low level input
current (TTL)
IIL2
VIL = 0.2V
V
IOVCC
–1.5
IOVCC
–1.3
V
V
V
2.0
0.8
V
–10
–5
µA
–20
0
µA
1.00
nA
HOLD characteristics
RC1 input pin leak current
Ileak
HOLD signal set-up time
Ths
20
ns
HOLD signal hold time
Thh
20
ns
PECLVCC
–1.6
V
Digital output
Digital high level output
voltage (PECL)
VOH1
RL = 330Ω
Digital low level output
voltage (PECL)
VOL1
RL = 330Ω
PECL output reference
voltage
VBB
RL = 330Ω
Digital high level output
voltage (TTL)
VOH2
CL = 10pF
Digital low level output
voltage (TTL)
VOL2
CL = 10pF
– 13 –
PECLVCC
–1.8
PECLVCC
–1.7
V
V
2.4
V
0.5
V
CXA3266Q
Item
Symbol
Conditions
Min.
Typ.
Max.
Unit
UNLOCK output
UNLOCK output current
Iunlock
mA
–30
SYNC input
SYNC input frequency range Fin
120
10
kHz
DSYNC output
DSYNC output coarse
delay time setting
resolution (upper)
Rdsync1
DSYNC output coarse
delay time (upper)
Td1
DSYNC output fine delay
time setting resolution
(lower)
Rdsync2
DSYNC output fine delay
time (lower)
Td2
8/32
48/32
CLK
DSYNC output DIVOUT
output delay time
Td9
4
5
CLK
bit
2
5
2
CLK
bit
6
VCO characteristics
DIV output frequency
operation range 1
FVCO1
DIV = 1/1
40
203
MHz
DIV output frequency
operation range 2
FVCO2
DIV = 1/2
20
100
MHz
DIV output frequency
operation range 3
FVCO3
DIV = 1/4
10
50
MHz
DIV output frequency
operation range 4
FVCO4
DIV = 1/8
5
25
MHz
VCO lock range
Vlock
2.0
4.4
V
VCO gain 1
KVCO1
DIV = 1/1
300
480
700
Mrad/sv
VCO gain 2
KVCO2
DIV = 1/2
150
240
350
Mrad/sv
VCO gain 3
KVCO3
DIV = 1/4
75
120
175
Mrad/sv
VCO gain 4
KVCO4
DIV = 1/8
37.5
60
87.5
Mrad/sv
Charge pump current 1
Kpd1
C.Pump Bit = 00,
IREF = 3.0kΩ
62.5
100
137.5
Charge pump current 2
Kpd2
C.Pump Bit = 01,
IREF = 3.0kΩ
125
200
275
Charge pump current 3
Kpd3
C.Pump Bit = 10,
IREF = 3.0kΩ
250
400
550
Change pump current 4
Kpd4
C.Pump Bit = 11,
IREF = 3.0kΩ
500
800
1100
VCO counter bits
Rdiv2
12
– 14 –
µA
µA
µA
µA
bit
CXA3266Q
Item
Symbol
Conditions
Min.
Typ.
Max.
Unit
CLK (CLK, CLK/2) output
CLK output (PECL)
frequency range 1
Fclk1PECL DIV = 1/1
40
203
MHz
CLK output (PECL)
frequency range 2
Fclk2PECL DIV = 1/2
20
100
MHz
CLK output (PECL)
frequency range 3
Fclk3PECL DIV = 1/4
10
50
MHz
CLK output (PECL)
frequency range 4
Fclk4PECL DIV = 1/8
5
25
MHz
CLK, CLK/2 output (PECL)
TrPECL
rise time
10% to 90%,
RL = 330Ω
1.0
2.0
3.0
ns
CLK, CLK/2 output (PECL)
TfPECL
fall time
10% to 90%,
RL = 330Ω
1.0
2.0
3.0
ns
CLK output (TTL)
frequency range 1
Fclk1TTL
DIV = 1/1
40
100
MHz
CLK output (TTL)
frequency range 2
Fclk2TTL
DIV = 1/2
20
100
MHz
CLK output (TTL)
frequency range 3
Fclk3TTL
DIV = 1/4
10
50
MHz
CLK output (TTL)
frequency range 4
Fclk4TTL
DIV = 1/8
5
25
MHz
CLK, CLK/2 output (TTL)
rise time
TrTTL
10% to 90%,
CL = 10pF
0.8
1.1
1.6
ns
CLK, CLK/2 output (TTL)
fall time
TfTTL
10% to 90%,
CL = 10pF
0.8
1.1
1.6
ns
CLK output (PECL, TTL)
duty
Dclk2
CL = 10pF
40
50
60
%
SYNC input (PECL) and
CLK output (PECL) delay
offset
Td3
CL = 10pF
1.0
1.6
2.2
ns
CLK output (PECL) and
DSYNC output (PECL)
phase difference
Td4
CL = 10pF
1.0
2.0
3.0
ns
CLK output (PECL) and
CLK/2 output (PECL)
phase difference
Td5
CL = 10pF
0.3
0.7
1.1
ns
DSYNC, CLK, CLK/2
output (PECL) and TTL
output phase difference
Td8
CL = 10pF
1.8
2.5
3.2
ns
– 15 –
CXA3266Q
Item
Symbol
Conditions
Min.
Typ.
Max.
Unit
Tj1p-p
triggered at SYNC
Fsync = 15.73kHz
Fclk = 12.27MHz
N = 780
1.8
2.5
4.0
ns
Tj2p-p
triggered at SYNC
Fsync = 31.47kHz
Fclk = 25.18MHz
N = 800
1.2
1.5
1.9
ns
Tj3p-p
triggered at SYNC
Fsync = 48.08kHz
Fclk = 50.00MHz
N = 1040
1.0
1.4
1.7
ns
Tj4p-p
triggered at SYNC
Fsync = 56.48kHz
Fclk = 75.00MHz
N = 1328
0.9
1.3
1.6
ns
Tj5p-p
triggered at SYNC
Fsync = 80kHz
Fclk = 136.00MHz
N = 1700
0.7
1.0
1.4
ns
Tj6p-p
triggered at SYNC
Fsync = 93.75kHz
Fclk = 202.50MHz
N = 2160
0.5
0.8
1.0
ns
triggered at DSYNC
0.1
ns
12
MHz
CLK (CLK, CLK/2) output
CLK vs. SYNC output jitter
(NTSC)
CLK vs. SYNC output jitter
(VGA)
CLK vs. SYNC output jitter
(SVGA)
CLK vs. SYNC output jitter
(XGA)
CLK vs. SYNC output jitter
(SXGA)
CLK vs. SYNC output jitter
(UXGA)
CLK vs. DSYNC output jitter Tj7p-p
Control registers
SCLK frequency
SCLK
in write/read mode
SENABLE set-up time
TENS
in write mode
3
ns
SENABLE hold time
TENH
in write mode
0
ns
SDATA set-up time
TDS
in write mode
3
ns
SDATA hold time
TDH
in read mode
0
ns
SENABLE set-up time
TNENS
in read mode
3
ns
SENABLE hold time
TNENH
in read mode
0
ns
– 16 –
CXA3266Q
Description of Block Diagram
Sync Input
Sync signals in the range of 10 to 120kHz can be input. Input supports both positive and negative polarity.
PECL input can also be a single input.
When SYNC is positive polarity, the clock is regenerated in synchronization with the rising edge of the sync signal.
When SYNC is negative polarity, the clock is regenerated in synchronization with the falling edge of the sync signal.
VCO oscillation stops when there is no sync input.
Register: SYNC POL
1
0
SYNC input polarity
Positive
Negative
Phase Detector
The phase detector operates at the sync input frequency of 10 to 120kHz. The PD input polarity should be
set to the default PD POL = 1. Phase comparison is performed at the edges.
The input circuit of the phase detector does not contain a hysteresis circuit, so the waveform must be shaped
at the front end of the CXA3266Q when inputting a noisy signal.
The phase detector HOLD signal is supplied by TTL. (See the HOLD Timing Chart.)
The PLL UNLOCK signal is output by an open collector.
(See the UNLOCK Timing Chart.)
Charge Pump
The gain (I, I/2, I/4, I/8) can be varied by changing the charge pump current using 2 bits of control register.
Register: C.Pump bit 1
0
0
1
1
Register: C.Pump bit 0
0
1
0
1
Charge pump current
100µA
200µA
400µA
800µA
LPF
This is a loop filter comprised of the external capacitors and resistor.
Be sure to use metal film resistors with little temperature variation and a temperature-compensated capacitor.
In particular, the 0.068µF capacitor should be equivalent to high dielectric constant series capacitor type B or
better. (electrostatic capacitance change ratio ±10%: T = –25 to +85°C)
VCO
The VCO oscillator frequency covers from 40 to 203MHz.
VCO Rear-end Counter
The VCO output is frequency divided to 1/1, 1/2, 1/4 or 1/8 by switching 2 bits of control register.
The operating range can be expanded to 5 to 203MHz by combining the counter with a VCO frequency divider.
Register: DIV 1, 2, 4, 8 bit 1
0
0
1
1
Register: DIV 1, 2, 4, 8 bit 0
0
1
0
1
Counter frequency divisions
1/1
1/2
1/4
1/8
– 17 –
CXA3266Q
Feedback Programmable Counter
This counter can be set as desired from 256 to 4096 using 12 bits.
Frequency divisions = (m + 1) × 8 + n, n: 3 bits (VCO DIV bits 0 to 2), m: 9 bits (VCO DIV bits 3 to 11)
When the register value is changed, the new setting is actually loaded to the counter when the counter value
becomes "all 0".
Clock Output
When SYNC input is positive polarity, the clock is regenerated in synchronization with the rising edge of the
sync signal.
The clock output delay time can be changed in the range of 8/32 to 48/32 CLK using 6 bits of control register.
(See the I/O Timing Chart.)
Output is TTL and PECL (complementary), and supports both positive and negative polarity. Clock TTL
output can also be turned off independently.
Register: Clock Enable
1
0
Clock output status
ON
OFF
1/2 Clock Output
Reset is performed at the delay sync timing and the clock output is frequency divided by 1/2. (See the I/O
Timing Chart.)
Both odd and even output are TTL and PECL output. TTL output can also be turned off independently.
Register: Clock Enable
1
0
Clock output status
ON
OFF
Delay Sync Output
The front edge of the delay sync pulse is latched by the pulse obtained by frequency dividing the CLK
regenerated by the PLL, so there is almost no jitter with respect to CLK. This front edge can be used as the
reset signal for the system timing circuit.
The rear edge of the delay sync pulse is latched by the CLK regenerated by the PLL. This relationship is
undefined for one clock as shown in the Timing Chart.
The delay sync output delay time can be varied in two stages. First, the delay time can be varied in the range
of 8/32 to 48/32 CLK using 6 bits of control register, and then in the range of 2 to 5 CLK using 2 bits of
control register. In other words, the total delay time is ((8/32 to 48/32) + (2 to 5)) CLK. (See the I/O Timing
Chart.)
DSYNC output is TTL and PECL (complementary), and supports both positive and negative polarity. Clock
TTL output can also be turned off.
Register: Clock Enable
1
0
Clock output status
ON
OFF
Lower delay line
FINE DELAY bits 0 to 5
000111
001000
· · · · · · · · · · · ·
101111
Delay time
8/32CLK
9/32CLK
· · · · · · · · · · · ·
48/32CLK
Upper delay line
COARSE DELAY bits 0 to 1
00
01
10
11
Delay time
2CLK
3CLK
4CLK
5CLK
Register: DSYNC POL
1
0
DSYNC output polarity
Positive
Negative
– 18 –
CXA3266Q
Programmable Counter TTL Output Switching
Output (PECL, TTL) from DSYNC output is possible by switching of control register.
1
0
Register: DSYNC By-pass
Output status from DSYNC DIVOUT output
DSYNC output
Delay Sync Output Width (DSYNC By-pass = 0)
Delay sync output pulse width can be varied to 1, 2, 4, or 8CLK by switching 2 bits of control register.
Register: DSYNC WIDTH
00
01
10
11
DSYNC width
1CLK
2CLK
4CLK
8CLK
Delay Sync Output Delay (DSYNC By-pass = 0)
DIVOUT output delay from delay sync output can be varied to 4 or 5CLK by switching of control register.
Register: DSYNC DELAY
0
1
Delay time
4CLK
5CLK
DSYNC Output Switching during HOLD
By switching with a control register, DSYNC output during HOLD period is controlled. Its output status is
different according to DSYNC By-pass, DSYNC POL and HOLD signals of the register. The output for each
setting is shown below.
Output from
DSYNC (Pin 24) and
DSYNCH (Pin 34)
Register
DSYNC Hold
Register
DSYNC By-pass
Register
DSYNC POL
Pin 6 HOLD
0
0
0
H
H
0
0
0
L
DIVOUT
0
0
1
H
L
0
0
1
L
DIVOUT
0
1
0
H
H
0
1
0
L
DSYNC
0
1
1
H
L
0
1
1
L
DSYNC
1
0
0
H
DIVOUT
1
0
0
L
DIVOUT
1
0
1
H
DIVOUT
1
0
1
L
DIVOUT
1
1
0
H
DSYNC
1
1
0
L
DSYNC
1
1
1
H
DSYNC
1
1
1
L
DSYNC
– 19 –
CXA3266Q
Control Circuit (3-bit address, 8-bit data)
The timing and input methods are described hereafter.
Feedback programmable counter control
VCO rear-end counter control
Fine delay line control
Coarse delay line control
Charge pump current DAC control
Phase detector input positive/negative polarity control
Delay sync output width control
Delay sync output delay control
Sync input positive/negative polarity control
Delay sync output positive/negative polarity control
Clock TTL output OFF function
Inverted clock TTL output OFF function
1/2 clock TTL output OFF function
Inverted 1/2 clock TTL output OFF function
Delay sync TTL output OFF function
UNLOCK output OFF function
Programmable counter input switching
Power save with register contents held
Register read function power ON/OFF
Programmable counter TTL output OFF function
Programmable counter TTL output switching
Delay sync output hold function
REGISTER1, 2
REGISTER3
REGISTER4
REGISTER4
REGISTER5
REGISTER5
REGISTER5
REGISTER5
REGISTER6
REGISTER6
REGISTER6
REGISTER6
REGISTER6
REGISTER6
REGISTER6
REGISTER6
REGISTER7
REGISTER7
REGISTER7
REGISTER7
REGISTER7
REGISTER7
12bit
2bit
6bit
2bit
2bit
1bit
2bit
1bit
1bit
1bit
1bit
1bit
1bit
1bit
1bit
1bit
1bit
1bit
1bit
1bit
1bit
1bit
VCODIV Bit0 to 11
DIV1, 2, 4, 8 Bit0, Bit1
FINE DELAY Bit0 to 5
COARSE DELAY Bit0, Bit1
C.Pump Bit0, Bit1
PD POL
DSYNC WIDTH
DSYNC DELAY
SYNC POL
DSYNC POL
CLK Enable
NCLK Enable
CLK/2 Enable
NCLK/2 Enable
DSYNC Enable
UNLOCK Enable
VCO By-pass
Synth power
Read out power
DIVOUT Enable
DSYNC By-pass
DSYNC Hold
Power Save
The CXA3266Q realizes 2-step power saving (all OFF, control registers only ON). This is controlled by a
control register and the chip selector.
Step 1: Chip selector control
CS
H
L
Power saving status
Power ON
All OFF
Step 2: Control register control
Register: Synth power
1
0
Power saving status
Power ON
Control registers only ON
Readout Circuit (during test mode)
The control register contents can be read by serial data from SEROUT.
(See the Control Register Timing Chart.)
Register: Read out power
Readout status
0
1
Function OFF Function ON
– 20 –
CXA3266Q
Programmable Counter Output (during test mode)
The programmable counter output is TTL output from the DIVOUT pin.
(See the I/O Timing Chart.)
This output is normally not used.
Register: DIVOUT Enable
0
1
DIVOUT output status
OFF
ON
TLOAD input (during test mode)
This control signal forcibly loads the control register contents to the programmable counter.
This signal is normally not used.
TLOAD
H
L
Forced load control status Function OFF Function ON
VCO input (during test mode)
This is the programmable counter test signal input pin.
This pin can be switched internally by the MUX circuit.
TTL and PECL input are possible.
This pin is normally not used.
Register: VCO By-pass
Input status
1
0
Internal VCO External input
– 21 –
CXA3266Q
Control Register Timing
1) Write mode
Many functions of the CXA3266Q can be controlled via a program. Characteristics are changed by setting the
internal control register values via a serial interface comprised of three pins: SENABLE (Pin 10), SCLK (Pin
11) and SDATA (Pin 12). The write timing diagram is shown below.
Input the 8-bit data and 3-bit register address MSB first to the SDATA pin. Some registers are not 8 bits, but
the data is input aligned with the LSB side in these cases. (See the Register Table.)
SENABLE is the enable signal and is active low. SCLK is the transfer clock signal, and data is loaded to the
IC at the rising edge. When SENABLE rises, SCLK must be high. (Registers are set at the rising edge of
SENABLE.) When SENABLE falls, SCLK may be either high or low.
SENABLE
8bit
DATA
SDATA
3bit
ADDRESS
SCLK
Enlarged
Enlarged
TENS
TENH
SENABLE
SDATA
SCLK
TDS TDH
For example, when inputting a 16-bit signal, the initial 5 bits are invalid and the latter 11 bits are valid. This is
to say that the latter 11 bits are loaded to the register.
SENABLE
SDATA
5bit
Invalid DATA
8bit
DATA
SCLK
– 22 –
3bit
address
CXA3266Q
The settings of the frequency divider (2 bits, DIV1, 2, 4, 8) and programmable counter (12 bits, VCODIV) at
the rear end of the VCO are transferred in the order shown below. (The data will be set when the three
registers are transferred.)
First DIVREG2, CENFREREG and DIVREG1 are set, and then the data is transferred independently at the
timings shown below.
DIVREG2 (upper 4 bits of VCODIV)
↓
CENFREREG (2 bits of DIV1, 2, 4, 8)
↓
DIVREG1 (lower 8 bits of VCODIV)
All three of the above registers must be changed even when changing only (2 bits of DIV1, 2, 4, 8). This is
the same when changing only (12 bits of VCODIV).
SENABLE
SDATA
SCLK
DIVREG2
CENFREREG
– 23 –
DIVREG1
CXA3266Q
2) Read mode
Data can be transferred from the shift register to the data register only when SENABLE is high.
Binary data can be read from the data register by inputting SCLK when SENABLE is high. Data is loaded
from the data register to the SCAN PATH circuit each time one clock is input to SCLK, and is output
sequentially from the register read no. 1 data (VCODIV bit 7) through the SEROUT pin. When the 42nd
SCLK clock pulse is input, the register read no. 42 data (VCO By-pass) is output. Then, when the 43rd clock
pulse is input to SCLK, the output returns to the register read no. 1 data (VCODIV bit 7) and the data output
is repeated. Also, the data output from the SCAN PATH circuit is automatically reloaded even when the shift
register data is changed during data output.
Note) Since all registers do not have 8 bits, only the valid bits of each register are loaded to the SCAN PATH
circuit. (See the Control Register Table for the actual register read no.)
SCLK
CLK
I/P SHIFT REGISTER, 11 BITS
NEN
SENABLE
8 BIT DATA
3 BIT ADDRESS
7 DATA REGISTERS (42 LATCHES).
REGISTERS ARE DIFFERENT LENGTHS
UP TO 8 BIT
TR
EN
CLK
SEROUT
SCAN PATH, 1 ELEMENT PER REGISTER BIT
Block Diagram during Read Mode
TNENS
TNENH
SENA
READ NO. 1
SEROUT
SCLK
1
READ NO. 2
2
Timing Chart during Read Mode
– 24 –
READ NO. N
N
– 25 –
A/D CONVERTER
P1 & P2 O/P
(TTL)
A/D CONVERTER
1/2CLK O/P
(TTL)
CLK/2 O/P
(N = ODD)
(PECL)
CLK/2 O/P
(N = EVEN)
(PECL)
DSYNC O/P (+VE POL)
(DSYNC By-pass = 0,
DSYNC Delay = 1)
(PECL)
DSYNC O/P (+VE POL)
(DSYNC By-pass = 0,
DSYNC Delay = 0)
(PECL)
RESET
(Internal Signal)
DSYNC O/P
(+VE POL)
(DSYNC By-pass = 1)
(PECL)
CLK O/P
(PECL)
SYNC I/P
(+VE POL)
(PECL)
Td3
(typ. 2ns)
Timing Chart (Td1 = 2CLK)
0
2
3
Td4
(typ. 2.0ns)
Td5
(typ. 0.7ns)
Td5
(typ. 0.7ns)
Td1 = 2CLK
Td2 = 1/32 to 64/32CLK
1CLK
1
5CLK
Td9 = 5CLK
Td9 = 4CLK
4
1, 2, 4, 8CLK
1, 2, 4, 8CLK
CXA3266Q
– 26 –
A/D CONVERTER
P1 & P2 O/P
(TTL)
A/D CONVERTER
1/2CLK O/P
(TTL)
CLK/2 O/P
(N = ODD)
(PECL)
CLK/2 O/P
(N = EVEN)
(PECL)
DSYNC O/P (+VE POL)
(DSYNC By-pass = 0,
DSYNC Delay = 1)
(PECL)
DSYNC O/P (+VE POL)
(DSYNC By-pass = 0,
DSYNC Delay = 0)
(PECL)
RESET
(Internl Signal)
DSYNC O/P
(+VE POL)
(DSYNC By-pass = 1)
(PECL)
CLK O/P
(PECL)
SYNC I/P
(+VE POL)
(PECL)
Td3
(typ. 2ns)
Timing Chart (Td1 = 3CLK)
0
2
Td1 = 3CLK
Td2 = 1/32 to 64/32CLK
1CLK
1
4
Td4
(typ. 2.0ns)
Td5
(typ. 0.7ns)
Td5
(typ. 0.7ns)
3
Td9 = 5CLK
Td9 = 4CLK
5CLK
1, 2, 4, 8CLK
1, 2, 4, 8CLK
CXA3266Q
– 27 –
A/D CONVERTER
P1 & P2 O/P
(TTL)
A/D CONVERTER
1/2CLK O/P
(TTL)
CLK/2 O/P
(N = ODD)
(PECL)
CLK/2 O/P
(N = EVEN)
(PECL)
DSYNC O/P (+VE POL)
(DSYNC By-pass = 0,
DSYNC Delay = 1)
(PECL)
DSYNC O/P (+VE POL)
(DSYNC By-pass = 0,
DSYNC Delay = 0)
(PECL)
RESET
(Internal Signal)
DSYNC O/P
(+VE POL)
(DSYNC By-pass = 1)
(PECL)
CLK O/P
(PECL)
SYNC I/P
(+VE POL)
(PECL)
Td3
(typ. 2ns)
Timing Chart (Td1 = 4CLK)
0
2
Td1 = 4CLK
Td2 = 1/32 to 64/32CLK
1CLK
1
3
5CLK
Td4
(typ. 2.0ns)
Td5
(typ. 0.7ns)
Td5
(typ. 0.7ns)
4
Td9 = 5CLK
Td9 = 4CLK
1, 2, 4, 8CLK
1, 2, 4, 8CLK
CXA3266Q
– 28 –
A/D CONVERTER
P1 & P2 O/P
(TTL)
A/D CONVERTER
1/2CLK O/P
(TTL)
CLK/2 O/P
(N = ODD)
(PECL)
CLK/2 O/P
(N = EVEN)
(PECL)
DSYNC O/P (+VE POL)
(DSYNC By-pass = 0,
DSYNC Delay = 1)
(PECL)
DSYNC O/P (+VE POL)
(DSYNC By-pass = 0,
DSYNC Delay = 0)
(PECL)
RESET
(Internal Signal)
DSYNC O/P
(+VE POL)
(DSYNC By-pass = 1)
(PECL)
CLK O/P
(PECL)
SYNC I/P
(+VE POL)
(PECL)
Td3
(typ. 2ns)
Timing Chart (Td1 = 5CLK)
0
2
3
Td1 = 5CLK
Td2 = 1/32 to 64/32CLK
1CLK
1
4
Td5
(typ. 0.7ns)
Td5
(typ. 0.7ns)
Td4
(typ. 2.0ns)
5CLK
Td9 = 5CLK
Td9 = 4CLK
1, 2, 4, 8CLK
1, 2, 4, 8CLK
CXA3266Q
CXA3266Q
2. HOLD timing
SYNC input
(SYNC POL = 1)
SYNC input
(SYNC POL = 0)
DIVOUT output
(TTL)
Thh
Ths
Thh
Ths
Thold
HOLD input
(TTL)
AA
A
AA
A
AA
The phase comparison output is held and fixed VCO output frequency is output.
CLK output
HOLD signal set-up time (Ths) is a time from the rising edge of HOLD signal to the falling edge of DIVOUT.
Or, when SYNC POL = 1, it is a time from the falling edge of HOLD signal to the rising edge of SYNC; when
SYNC POL = 0, it is the time from the falling edge of HOLD signal to the falling edge of SYNC.
HOLD signal hold time (Thh) is the time from the falling edge of DIVOUT to falling edge of HOLD signal. Or,
when SYNC POL = 1, it is the time from the rising edge of SYNC to the rising edge of HOLD signal; when
SYNC POL = 0, it is the time from the falling edge of SYNC to the rising edge of HOLD signal.
When the HOLD input is held, the CLK frequency fluctuation can be calculated as follows.
I
SW
+Q
∆V
–Q
C
Ileak
VCO
∆f
SW
I
C · ∆V = Q = Ileak · Thold
C:
∆V:
Ileak:
Thold:
Loop filter capacitance
Voltage variation due to leak current
Internal amplifier leak current
Hold time
∆V = Ileak · Thold/C
∆f = ∆V · KVCO = Ileak · Thold/C · KVCO
For example, assuming f = 100MHz, Ileak = 1nA, Thold = 1ms, C = 0.068µF, and KVCO = 2π · 75MHz, then:
∆V = 1 × 10–9 · 1 × 10–3/(0.068 × 10–6) = 15 × 10–6 [V]
∆f = 1 × 10–9 · 1 × 10–3/(0.068 × 10–6) · 75 × 106 = 1125 [Hz]
– 29 –
CXA3266Q
3. Relationship between SYNC input and DSYNC output during HOLD
SYNC
internal signal
J
DIVOUTN
internal signal
K
DSYNC
internal signal
Q
CK
Q
CLK
When the above SYNC internal and DIVOUTN internal signals are input, the DSYNC internal signal is output
as shown in the table below.
1. DSYNC = L when SYNC = L and DIVOUTN = L.
2. DSYNC = H∗ or L∗ (unchanged with the previous data) when SYNC = H and DIVOUTN = L.
3. DSYNC = H when DIVOUTN = H (SYNC = H or L)
SYNC
DIVOUTN
L
L
L
H
H
L
H
H
J
K
Q
Q
DSYNC
L∗
L
L
L∗
L∗
(1)
H
L
H
L
L
(2)
L
H
L
H
H
(3)
L
L
L
L∗
H∗
H∗
L∗
H∗
L∗
L
L
H
L
H
H
(4)
(5)
(6)
(∗) is unchanged with the previous data.
SYNC
internal signal
DIVOUTN
internal signal
DSYNC
internal signal
(1)
(5)
(6)
(4)
– 30 –
(2)
(3)
CXA3266Q
During HOLD, the output from DSYNC can be controlled by register DSYNC hold. Its output status differs
according to the DSYNC polarity or DSYNC By-pass switching. The below diagrams show the relationship with
DSYNC output for each SYNC input.
(DSYNC POL = 1 for all of CASE1 to CASE3.)
CASE1
HSYNC
(SYNC POL = 1)
HOLD input
(1) During DSYNC
HOLD ON
(DSYNC Hold = 1)
DSYNC By-pass = 1
DSYNC By-pass = 0
(2) During DSYNC
HOLD OFF
(DSYNC Hold = 0)
DSYNC By-pass = 1
DSYNC By-pass = 0
CASE2
HSYNC
(SYNC POL = 1)
HOLD input
(1) During DSYNC
HOLD ON
(DSYNC Hold = 1)
DSYNC By-pass = 1
DSYNC By-pass = 0
(2) During DSYNC
HOLD OFF
(DSYNC Hold = 0)
DSYNC By-pass = 1
DSYNC By-pass = 0
– 31 –
CXA3266Q
CASE3
HSYNC
(SYNC POL = 1)
HOLD input
(1) During DSYNC
HOLD ON
(DSYNC Hold = 1)
DSYNC By-pass = 1
DSYNC By-pass = 0
(2) During DSYNC
HOLD OFF
(DSYNC Hold = 0)
DSYNC By-pass = 1
DSYNC By-pass = 0
– 32 –
CXA3266Q
4. UNLOCK timing
Inside the IC
Outside the IC
VCC
I2
R2
R1
Signal from phase
comparator
unlock
detect
S1
I1
UNLOCK
S2
C
The unlock detect output is an open collector. When unlock detect output S1 goes high, the current I1 is pulled in.
The UNLOCK sensitivity can be adjusted by connecting external resistors (R1, R2) and a capacitor (C) to this output
pin appropriately and changing these values. Operation during three modes is described below.
CASE 1: When there is no phase difference, that is to say, when the PLL is locked.
The S1 signal is low and the S2 signal is high.
The UNLOCK output remains low.
S1
S2
threshold
level
UNLOCK
CASE 2: When there is a phase difference, that is to say, when the S1 signal goes high and low as shown in
the figure below, the fall slew rate of the S2 signal is determined by the current I1 flowing into that
open collector. Therefore, increasing the resistance R1 causes the S2 signal fall slew rate to
become slower. Also, since the S2 signal rise slew rate is determined by the current I2, reducing
the resistance R2 causes the S2 signal rise slew rate to become faster. If this integrated S2 signal
does not fall below the threshold level of the next inverter, the UNLOCK signal stays low, and the
PLL is said to be locked.
S1
S2
threshold
level
UNLOCK
CASE 3: However, even if a phase difference exists as shown above, if the resistance R1 is reduced, the
current I1 flowing into the open collector increases, and the S2 signal fall slew rate becomes faster.
Also, if the resistance R2 is increased, the S2 signal rise slew rate becomes slower. If this
integrated S2 signal falls below the threshold level of the next inverter, the UNLOCK signal goes
from low to high, and the PLL is said to be unlocked.
S1
threshold
level
S2
UNLOCK
– 33 –
CXA3266Q
Charge Pump and Loop Filter Settings
The CXA3266Q's charge pump is a constant-current output type as shown below.
When a constant-current output charge pump circuit is used inside the PLL,
the phase detector output acts as a current source, and the dimension of its
transmittance KPD is A/rad. Also, when considering the VCO input as a
voltage, the LPF transmittance dimension must be expressed in ohms (Ω =
V/A).
Therefore, the PLL transmittance when a constant-current output charge
pump circuit is used is as follows.
VCC
S1
To LPF
S2
ωr
1/S
θr
+
PD
LPF
VCO
KPD
(A/rad)
F (S)
(Ω)
KVCO
(rad/sV)
–
θo
N
1/S
counter
ω0/N
1/N
The PLL closed loop transmittance is obtained by the following formula.
θo/N
θr
=
KPD · F (S) · KVCO · 1/N · 1/S
... (1)
1 + KPD · F (S) · KVCO · 1/N · 1/S
Here, KPD, F (S), and KVCO are:
KPD: Phase comparator gain
F (S): Loop filter transmittance
KVCO: VCO gain
(A/rad)
(Ω)
(rad/sV)
∗1 The reason for the 1/S inside the phase detector is as follows.
t
θo (t)/N = ∫ o ω0 (t)/Ndt + θo (t = 0)/N ... (a)
If θo (t = 0) = 0,
t
θo (t)/N = ∫ o ω0 (t)/Ndt ... (b)
Performing Laplace conversion:
θo (S)/N = 1 W0 (S)/N ... (c)
s
– 34 –
ω0
CXA3266Q
The loop filter F (s) is described below.
The loop filter smoothes the output pulse from the phase comparator and inputs it as the DC component to the
VCO. In addition to this, however, the loop filter also plays an important element in determining the PLL
response characteristics.
Typical examples of loop filters include lag filters, lag-lead filters, active filters, etc. However, the CXA3266Q's
LPF is a current input type active filter as shown below, so the following calculations show an actual example
of deriving the PLL closed loop transmittance when using this type of filter and then using this transmittance to
create a formula for setting the filter constants.
Current input type active filter
C
R
ii
–A
–1
Vo
–Vo
The Bode diagram for formula (2) is as follows.
F (S) =
=
gain [dB]
VO
1
+ VO = (R +
)
A
SC
1 + SRC
A
·
SC
1+A
log scale
The filter transmittance is as follows.
1
τ
log w
1 + Sτ
A
·
SC
1+A
∴τ = RC
log w
phase [deg]
0
Here, assuming A > 1, then:
F (S) =
1 + Sτ ...........................
(2)
SC
–45deg
–90
Next, substituting (2) into (1) and obtaining the overall closed loop transmittance for the PLL:
θo/N
θr
KPD · KVCO · τ
NC
=
KPD · KVCO · τ
NC
S2 +
=
ωn =
ζ=
S2
√
·S+
2ζωnS + ωn2
+ 2ζωnS + ωn2
KPD · KVCO
NC
... (3)
KPD · KVCO
·S+
NC
............................................ (4)
KPD · KVCO ......................................................
(5)
NC
1
2
ωnτ ................................................................. (6)
– 35 –
CXA3266Q
Here, ωn and ζ are as follows.
ωn characteristic angular frequency:
The oscillatory angular frequency when PLL oscillation is assumed to have been maintained by the loop filter
and individual loop gains is called the characteristic angular frequency: ωn.
ζ damping factor:
This is the PLL transient response characteristic, and serves as a measure of the PLL stability. It is
determined by the loop gain and the loop filter.
A capacitor C2 is added to the actual loop filter.
This added capacitor C2 is used to reduce the R noise, and a value of around 1/10 to 1/1000 of C1 should be
selected as necessary.
Current input type active filter with added capacitor C2
C2
C1
R
ii
–1
–A
Vo
–Vo
1 + C1 · R · S
S ((C1 + C2) + C1 · C2 · R · S)
gain [dB]
F (S) =
The Bode diagram for formula (7) is as follows.
1 + τ1 · S
.................. (7)
=
S (C1 + C2) (1 + τ2 · S)
log scale
The filter transmittance is as follows.
τ1 = C1 · R
τ2 =
log w
C1 · C2 · R
C1 + C2
log w
phase [deg]
0
Here, assuming C2 = C1/100, then:
τ2 =
C1 · C1/100 · R
C1 + C1/100
=
1
C1 · R
101
=
1
τ1
101
–45deg
–90
– 36 –
1
1
τ1
τ2
CXA3266Q
Next, the various parameters inside an actual CXA3266Q are obtained.
The CXA3266Q's charge pump output block and the LPF circuit are as follows.
C2
R1 C1
46
45
CXA3266Q
VCC
333
100µA
or 200µA
or 400µA
or 800µA
S1
To VCO
100µA
or 200µA
or 400µA
or 800µA
S2
20k
100
First, KPD is as follows.
KPD = 100µ/2π or 200µ/2π or 400µ/2π or 800µ/2 π (A/rad)
Typical KVCO characteristics curves for the CXA3266Q's internal VCO are as follows.
250
VCO frequency [MHz]
VCO DIV = 1/1
200
150
VCO DIV = 1/2
100
VCO DIV = 1/4
50
VCO DIV = 1/8
0
2
3
VCO input voltage [V]
4
Therefore, KVCO is as follows.
KVCO = 2π · 75M or 2π · 37.5M or 2π · 18.75M or 2π · 9.375M (rad/sV)
– 37 –
CXA3266Q
ωn and ζ calculated for various types of computer signals are shown below.
Here, the various parameters are as follows.
FSYNC: Input H sync frequency
FCLK: Output clock frequency
KPD × 2π: Phase comparator gain × 2π (KPD × 2π = +100 or 200 or 400 or 800)
KVCO/2π: VCO gain
(when VCO DIV = 1/1, KVCO/2π = 75)
(when VCO DIV = 1/2, KVCO/2π = 75/2)
(when VCO DIV = 1/4, KVCO/2π = 75/4)
(when VCO DIV = 1/8, KVCO/2π = 75/8)
N: Counter value
C1: Loop filter capacitance value
R1: Loop filter resistance value
MODE Resolution HSYNC FCLK
kHz
MHz
KPD C.Pump
N
DIV1, 2, 4, 8
C1
KVCO/2π
× 2π setting
setting setting
µA Bit1 Bit0 M/(S × V) Bit1 Bit0
µF
R1
ωn
fn
ζ
kΩ kHzrad kHz
NTSC
15.73 12.27
400
1
0
75/8
1
1
780 0.068 3.0
8.41
1.34 0.86
NTSC
15.73 18.41
400
1
0
75/8
1
1
1170 0.068 3.0
6.87
1.09 0.70
NTSC
15.73 24.55
800
1
1
75/8
1
1
1560 0.068 3.0
8.41
1.34 0.86
PAL
15.63 14.69
400
1
0
75/8
1
1
940 0.068 3.0
7.66
1.22 0.78
PAL
15.63 22.03
800
1
1
75/8
1
1
1410 0.068 3.0
8.84
1.41 0.90
PAL
15.63 29.38
400
1
0
75/4
1
0
1880 0.068 3.0
7.66
1.22 0.78
PC-98 640 × 400 24.82 21.05
400
1
0
75/8
1
1
848 0.068 3.0
8.06
1.28 0.82
VGA
640 × 480 31.47 25.18
400
1
0
75/8
1
1
800 0.068 3.0
8.30
1.32 0.85
MAC
640 × 480 35.00 30.24
400
1
0
75/4
1
0
864 0.068 3.0
11.30 1.80 1.15
VESA 640 × 480 37.86 31.50
400
1
0
75/4
1
0
832 0.068 3.0
11.51 1.83 1.17
SVGA 800 × 600 35.16 36.00
400
1
0
75/4
1
0
1024 0.068 3.0
10.38 1.65 1.06
SVGA 800 × 600 37.88 40.00
400
1
0
75/4
1
0
1056 0.068 3.0
10.22 1.63 1.04
SVGA 800 × 600 46.88 49.51
400
1
0
75/4
1
0
1056 0.068 3.0
10.22 1.63 1.04
SVGA 800 × 600 48.08 50.00
400
1
0
75/4
1
0
1040 0.068 3.0
10.30 1.64 1.05
SVGA 800 × 600 53.67 56.25
400
1
0
75/2
0
1
1048 0.068 3.0
14.51 2.31 1.48
832 × 624 49.72 57.28
400
1
0
75/2
0
1
1152 0.068 3.0
13.84 2.20 1.41
XGA 1024 × 768 48.36 65.00
400
1
0
75/2
0
1
1344 0.068 3.0
12.81 2.04 1.31
XGA 1024 × 768 56.48 75.01
400
1
0
75/2
0
1
1328 0.068 3.0
12.89 2.05 1.31
XGA 1024 × 768 60.02 78.75
400
1
0
75/2
0
1
1312 0.068 3.0
12.97 2.06 1.32
MAC 1024 × 768 60.24 80.00
400
1
0
75/2
0
1
1328 0.068 3.0
12.89 2.05 1.31
XGA 1024 × 768 68.68 94.50
400
1
0
75/2
0
1
1376 0.068 3.0
12.66 2.02 1.29
SXGA 1280 × 1024 46.43 78.75
400
1
0
75/2
0
1
1696 0.068 3.0
11.40 1.82 1.16
SXGA 1280 × 1024 63.98 108.00 400
1
0
75/1
0
0
1688 0.068 3.0
16.17 2.57 1.65
SXGA 1280 × 1024 79.98 135.01 400
1
0
75/1
0
0
1688 0.068 3.0
16.17 2.57 1.65
SXGA 1280 × 1024 91.15 156.96 400
1
0
75/1
0
0
1722 0.068 3.0
16.01 2.55 1.63
UXGA 1600 × 1200 81.23 175.46 800
1
1
75/1
0
0
2160 0.068 3.0
20.21 3.22 2.06
UXGA 1600 × 1200 93.72 202.44 800
1
1
75/1
0
0
2160 0.068 3.0
20.21 3.22 2.06
MAC
– 38 –
CXA3266Q
CLK Jitter Evaluation Method
The regenerated CLK is obtained by applying Hsync to the CXA3266Q. Apply this CLK to a digital oscilloscope
and observe the CLK waveform using Hsync as the trigger.
trigger
Pulse
Generator
Hsync
CXA3266Q
CLK
H
Back
Sync Porch
ch1
Digital
Oscilloscope
Active
Video
Front
Porch
Computer signal
15 to 25% of Tsync
Hsync
Tsync = 1/fsync
CLK
Enlarged
Enlarged
Enlarged
Enlarged
Trigger
CLK
Tjp-p
The CLK jitter is measured at peak to peak in the long-term write mode of the digital oscilloscope as shown in
the figure. The CLK jitter size varies according to the difference in the relative position with respect to Hsync.
Therefore, when the observation point is changed, the CLK jitter at that point is observed.
Jitter amount [Tjp-p]
The figure below shows an typical example of the CLK jitter for the CXA3266Q.
The CLK jitter increases slightly at the rising edge of Hsync (in the case of positive polarity), and then settles
down thereafter. However, this is not a problem as the active pixels start after about 20% of the H cycle has
passed from the rising edge of Hsync.
0
1/4 · Tsync
2/4 · Tsync
Observation points
– 39 –
3/4 · Tsync
Tsync
CXA3266Q
Example of Representative Characteristics
KVCO characteristics
KVCO temperature characteristics
250
250
DIV = 1/1
Ta = +75°C
Ta = +25°C
Ta = –25°C
200
Output frequency [MHz]
Output frequency [MHz]
200
150
DIV = 1/2
100
DIV = 1/4
50
150
100
50
DIV = 1/8
0
0
1.5
2.0
2.5
3.0
3.5
VCO control voltage [V]
4.0
4.5
1.5
2.0
2.5
3.0
3.5
VCO control voltage [V]
Fine delay Td2 vs. Fine delay bit
Ta = +75°C
Ta = +25°C
Ta = –25°C
40
32
24
16
8
8
16
24
32
Fine delay bit
40
48
Jitter peak-peak vs. Output frequency
2.5
NTSC, DIV = 1/8, CP = 10, 11
VGA, DIV = 1/8, 1/4, CP = 10
SVGA, DIV = 1/4, CP = 10
XGA, DIV = 1/2, CP = 10
SXGA, DIV = 1/1, CP = 10
UXGA, DIV = 1/1, CP = 11
2.0
Jitter peak-peak [ns]
Fine delay Td2 [1/32 CLK]
48
1.5
1.0
0.5
0
0
20
40
60
80 100 120 140 160
Output frequency [MHz]
– 40 –
180
200
220
4.0
4.5
CXA3266Q
Notes on Operation
• Be sure not to separate the analog and digital power supplies, and the analog and digital GND.
• The ground pattern should be as wide as possible. Using a multi-layer substrate with a mat ground is
recommended.
• Ground the power supply pins of the IC with a 0.1µF or larger ceramic chip capacitor as close to each pin as
possible.
• Be sure to accurately match the I/O characteristic impedance in order to ensure sufficient performance during
high-speed operation.
• Design the set so that the loop filter (external) is located at the minimum distance. (See the CXA3266Q
PWB.)
• The voltage applied to VOCLP pin must be supplied from the stabilized power supplies (3-pin regulator etc.)
because of the construction of internal circuit.
– 41 –
CXA3266Q
(1) Recommended PECL I/O circuit
The peripheral circuits mainly use PECL for digital input and output. Of course, PECL and TTL can also be
mixed. In this case, disable the TTL outputs with the control registers.
PECL level output pins
330Ω
33
32
31
30
29
28
27
DSYNCL
CLKH
CLKL
CLK/2H
CLK/2L
PECLVCC
IOGND
26
TTLVCC
34
25
TTLGND
35
DSYNCH
37 IOGND
PECLVCC
36
VBB
GND
DSYNC 24
38 VOCLP
CLK 23
39 PLLVCC
CLKN 22
40 PLLGND
CLK/2 21
41 VCOVCC
CLK/2N 20
42 VCOGND
100pF
0.068µF
DGND 19
43 VCOHGND
∗3
VCC
DVCC 18
3.0kΩ
100Ω
44 IREF
UNLOCK 17
45 RC2
DIVOUT 16
46 RC1
SEROUT 15
100kΩ
10nF
680pF
GND
3.0kΩ
Loop Filter∗4
47 IRGND
IOVCC
IOGND
VCOH
VCOL
VCO
HOLD
SYNCH
SYNCL
SYNC
SENABLE
SCLK
SDATA
48
CS 14
1
2
3
4
5
6
7
8
9
10
11
12
IRVCC
TLOAD
GND
VCC (+5.0V)
Control
Register
Notes)
∗1 Unless otherwise specified, all capacitors are 0.1µF.
∗2 Vary the external resistor and capacitor values of the
UNLOCK output as necessary.
∗3 This external resistor (3.0kΩ) should be a metal film
resistor in consideration of temperature characteristics.
∗4 The loop filter's capacitors and resistor should also be
temperature compensated.
13
HOLD
SYNCH, SYNCL: PECL level
complementary input
– 42 –
UNLOCK output∗2
CXA3266Q
34
33
32
31
30
29
28
27
26
DSYNCL
CLKH
CLKL
CLK/2H
CLK/2L
PECLVCC
IOGND
TTLVCC
25
TTLGND
35
DSYNCH
37 IOGND
PECLVCC
36
VBB
(2) Recommended TTL I/O circuit
The peripheral circuits mainly use TTL for digital input and output. Of course, PECL and TTL can also be
mixed.
TTL level output pins
DSYNC 24
38 VOCLP
CLK 23
39 PLLVCC
CLKN 22
40 PLLGND
CLK/2 21
41 VCOVCC
CLK/2N 20
42 VCOGND
100pF
0.068µF
DGND 19
43 VCOHGND
∗3
VCC
DVCC 18
3.0kΩ
100Ω
44 IREF
UNLOCK 17
45 RC2
DIVOUT 16
46 RC1
SEROUT 15
100kΩ
10nF
680pF
GND
3.0kΩ
Loop Filter∗4
47 IRGND
IOVCC
IOGND
VCOH
VCOL
VCO
HOLD
SYNCH
SYNCL
SYNC
SENABLE
SCLK
SDATA
48
CS 14
1
2
3
4
5
6
7
8
9
10
11
12
IRVCC
TLOAD
GND
VCC (+5.0V)
Control
Register
Notes)
∗1 Unless otherwise specified, all capacitors are 0.1µF.
∗2 Vary the external resistor and capacitor values of the
UNLOCK output as necessary.
∗3 This external resistor (3.0kΩ) should be a metal film
13
HOLD
SYNC: TTL level input
resistor in consideration of temperature characteristics.
∗4 The loop filter's capacitors and resistor should also be
temperature compensated.
– 43 –
UNLOCK output∗2
CXA3266Q
Connecting the CXA3266Q with Sony ADC (Demultiplex Mode)
When connecting the PLL output to A/D converters with built-in demultiplex function such as the
CXA3246Q/CXA3276Q/CXA3256R/CXA3286R (Sony), a simple system can be configured by connecting the
CLK (PECL) and CLKN (PECL) outputs of the CXA3266Q to the CLK (PECL) and CLKN (PECL) inputs of
each A/D converter, respectively, and the 1/2 CLK (PECL) and 1/2 CLKN (PECL) outputs of the CXA3266Q
to the RESETN (PECL) and RESET (PECL) inputs of each A/D converter, respectively (when the PLL
counter value N is an even number).
Wiring Diagram
8
VIN
G
8
B
VIN
CLK (PECL)
CLKN (PECL)
TTL
8
TTL
8
ADC
CXA3246Q
CXA3276Q
CXA3256R
CXA3286R
DSYNC (TTL)
1/2 CLK (PECL)
1/2 CLKN (PECL)
CLK (PECL)
CLKN (PECL)
RESETN (PECL)
RESET (PECL)
ADC
CXA3246Q
CXA3276Q
CXA3256R
CXA3286R
1/2 CLK
(TTL)
RESETN (PECL)
RESET (PECL)
8
TTL
VIN
CLK (PECL)
CLKN (PECL)
TTL
CMOS LOGIC
RESETN (PECL)
RESET (PECL)
ADC
CXA3246Q
CXA3276Q
CXA3256R
CXA3286R
TTL
8
TTL
• CXA3246Q
• CXA3276Q
• CXA3256R
• CXA3286R
PLL
CXA3266Q
– 44 –
RESET (TTL)
CLK (PECL)
CLKN (PECL)
CLK (TTL)
R
8-bit 120MSPS ADC
8-bit 160MSPS ADC
8-bit 120MSPS ADC
8-bit 160MSPS ADC
CXA3266Q
CXA3266Q and Sony ADC (Demultiplex Mode) Timing: 120MHz specification
The CXA3266Q and CXA3246Q/CXA3256R timings are shown below.
Here, the important timings are as follows.
(The clock cycle is labeled as T.)
• For the A/D converters
Clock input vs. reset input
The set-up time is T–1.1ns and the hold time is 0.3ns, satisfying the A/D converter specifications.
• For the CMOS LOGIC at the rear end of the A/D converters
A/D converter data output vs. 1/2 clock output timing
The set-up time is T–4.5ns and the hold time is T–3.5ns. (These timings also include combinations of
three A/D converters from different lots, and are defined for all operating temperatures and all operating
supply voltages. See the CXA3246Q/CXA3256R data sheets for a detailed description.)
• For the CMOS LOGIC at the rear end of the A/D converters
DSYNC signal from CXA3266Q vs. A/D converter 1/2 clock output
The set-up time is T–3.2ns and the hold time is T–4.2ns.
CXA3266Q
T
CLK (PECL)
out
2.8 to 6.2ns
DSYNC (TTL)
out
0.3 to 1.1ns
1/2CLK (PECL)
out
∗ See the CXA3246Q and
CXA3256R data sheets.
CXA3246Q
CXA3256R
Thold min.
3.0 to 7.0ns T–4.2ns
Tsetup min.
T–3.2ns
1/2CLK (TTL)
out
DATA (TTL)
out
– 45 –
Tsetup min. Thold min.
T–4.5ns
T–3.5ns
CXA3266Q
CXA3266Q and Sony ADC (Demultiplex Mode) Timing: 160MHz specification
The CXA3266Q and CXA3276Q/CXA3286R timings are shown below.
Here, the important timings are as follows.
(The clock cycle is labeled as T.)
• For the A/D converters
Clock input vs. reset input
The set-up time is T–1.1ns and the hold time is 0.3ns, satisfying the A/D converter specifications.
• For the CMOS LOGIC at the rear end of the A/D converters
A/D converter data output vs. 1/2 clock output timing
The set-up time is T–4.0ns and the hold time is T–3.0ns. (These timings also include combinations of
three A/D converters from different lots, and are defined for all operating temperatures and all operating
supply voltages. See the CXA3276Q/CXA3286R data sheets for a detailed description.)
• For the CMOS LOGIC at the rear end of the A/D converters
DSYNC signal from CXA3266Q vs. 1/2 clock output of A/D converter
The set-up time is T–3.2ns and the hold time is T–3.7ns.
CXA3266Q
T
CLK (PECL)
out
2.8 to 6.2ns
DSYNC (TTL)
out
0.3 to 1.1ns
1/2CLK (PECL)
out
∗ See the CXA3276Q and
CXA3286R data sheets.
CXA3276Q
CXA3286R
Thold min.
3.0 to 6.5ns T–3.7ns
Tsetup min.
T–3.2ns
1/2CLK (TTL)
out
DATA (TTL)
out
– 46 –
Tsetup min. Thold min.
T–4.0ns
T–3.0ns
CXA3266Q
Connecting the CXA3266Q with Sony ADC (Straight Mode)
When connecting the PLL output to A/D converters such as the CXA3246Q/CXA3276Q/CXA3256R/CXA3286R
(Sony), a simple system can be configured as shown below.
Wiring Diagram
8
VIN
8
VIN
CLK (PECL)
CLKN (PECL)
B
TTL
ADC
CXA3246Q
CXA3276Q
CXA3256R
CXA3286R
8
VIN
TTL
ADC
CXA3246Q
CXA3276Q
CXA3256R
CXA3286R
DSYNC (TTL)
CLK (TTL)
CLK (PECL)
CLKN (PECL)
CLK (PECL)
CLKN (PECL)
CMOS LOGIC
G
TTL
ADC
CXA3246Q
CXA3276Q
CXA3256R
CXA3286R
• CXA3246Q
• CXA3276Q
• CXA3256R
• CXA3286R
PLL
CXA3266Q
– 47 –
RESET (TTL)
CLK (PECL)
CLKN (PECL)
CLK (TTL)
R
8-bit 120MSPS ADC
8-bit 160MSPS ADC
8-bit 120MSPS ADC
8-bit 160MSPS ADC
CXA3266Q
CXA3266Q and Sony ADC (Straight Mode) Timing: 100MHz specification
The CXA3266Q and CXA3246Q/CXA3256R timings are shown below.
Here, the important timings are as follows.
(The clock cycle is labeled as T.)
• For the CMOS LOGIC at the rear end of the A/D converters
A/D converter data output vs. clock output from CXA3266Q
The set-up time is T–5.7ns and the hold time is 0.3ns. (These timings also include combinations of three
A/D converters from different lots, and are defined for all operating temperatures and all operating supply
voltages. See the CXA3246Q/CXA3256R data sheets for a detailed description.)
• For the CMOS LOGIC at the rear end of the A/D converters
DSYNC signal from CXA3266Q vs. A/D converter clock output
The set-up time is T–3.0ns and the hold time is T–1.0ns.
CXA3266Q
T
CLK (PECL)
out
1.8 to 3.2ns
CLK (TTL)
out
1.0 to 3.0ns
DSYNC (TTL)
out
Thold min.
1.0ns
Tsetup min.
T–3.0ns
CXA3246Q
CXA3256R
Tsetup min.
T–5.7ns
Thold min.
0.3ns
3.5ns min.
DATA (TTL)
out
7.5ns max.
– 48 –
CXA3266Q
CXA3266Q and Sony ADC (Straight Mode) Timing: 100MHz specification
The CXA3266Q and CXA3276Q/CXA3286R timings are shown below.
Here, the important timings are as follows.
(The clock cycle is labeled as T.)
• For the CMOS LOGIC at the rear end of the A/D converters
A/D converter data output vs. clock output from CXA3266Q
The set-up time is T–5.2ns and the hold time is 0.3ns. (These timings also include combinations of three
A/D converters from different lots, and are defined for all operating temperatures and all operating supply
voltages. See the CXA3276Q/CXA3286R data sheets for a detailed description.)
• For the CMOS LOGIC at the rear end of the A/D converters
DSYNC signal from CXA3266Q vs. A/D converter clock output
The set-up time is T–3.0ns and the hold time is T–1.0ns.
CXA3266Q
T
CLK (PECL)
out
1.8 to 3.2ns
CLK (TTL)
out
1.0 to 3.0ns
DSYNC (TTL)
out
Thold min.
1.0ns
Tsetup min.
T–3.0ns
CXA3276Q
CXA3286R
Tsetup min.
T–5.2ns
Thold min.
0.3ns
3.5ns min.
DATA (TTL)
out
7.0ns max.
– 49 –
CXA3266Q
CXA3266Q-PWB (CXA3266Q Evaluation Board)
The CXA3266Q-PWB is an evaluation board for the CXA3266Q PLL-IC. This board makes it possible to easily
evaluate the CXA3266Q's performance using the supplied control program (Note: IBM PC/AT, MS-DOS 5.0 or
newer US mode specifications).
Features
• Two input level (TTL and PECL) SYNC input
• Two output level (TTL and PECL) CLK, CLK2 and DSYNC output
• Supply voltage: +5.0V
Absolute Maximum Ratings (Ta = 25°C)
Supply voltage
VCC
–0.5 to +7.0
Recommended Operating Conditions
• Supply voltage
VCC
4.75 to 5.25
GND
0
• Digital input
(PECL)
DIN (High)
DIN (Low)
(TTL)
DIN (High)
DIN (Low)
• Operating ambient temperature
Ta
–20 to +75
V
V
V
VCC – 1.1
VCC – 1.5
GND + 2.0
GND + 0.8
V (Min.)
V (Max.)
V (Min.)
V (Max.)
°C
Block Diagram
Loop Filter
VCO input
(PECL/TTL)
DSYNC output
(PECL/TTL)
CXA3266Q
48pin QFP
SYNC input
(PECL/TTL)
CLK output
(PECL/TTL)
CLK/2 output
(PECL/TTL)
VBB (PECL)
SEROUT (TTL)
3
DIVOUT (TTL)
UNLOCK (TTL)
CONTROL BUS (TTL)
SENABLE, SCLK, SDATA
– 50 –
CXA3266Q
Setting Methods and Notes on Operation
Input pins
This PWB supports TTL single and PECL complementary input.
Input pins: SYNC: TTL level input, 10 to 120kHz
SYNCL: PECL low level input, 10 to 120kHz
SYNCH: PECL high level input, 10 to 120kHz
VCO:
VCOL:
VCOH:
TTL level input. This is a test pin and is therefore normally not used.
PECL low level input. This is a test pin and is therefore normally not used.
PECL high level input. This is a test pin and is therefore normally not used.
Output pins
This PWB supports TTL single and PECL complementary output.
DSYNCH,
DSYNCL: PECL level complementary delay SYNC outputs. The output range is 10 to 120kHz.
DSYNC:
TTL level delay SYNC output. The output range is 10 to 120kHz.
CLKH,
CLKL:
PECL level complementary CLK outputs. The output range is 10 to 203MHz.
CLK,
CLKN:
TTL level complementary CLK outputs. The output range is 10 to 100MHz.
CLK/2H,
CLK/2L:
PECL level complementary 1/2 CLK outputs. The output range is 5 to 100MHz.
CLK/2,
CLK/2N:
TTL level complementary CLK outputs. The output range is 5 to 100MHz.
VBB:
Outputs the PECL amplitude threshold voltage.
SEROUT: TTL level control register serial data output.
DIVOUT: TTL level internal programmable counter test output.
UNLOCK: TTL level UNLOCK output. This pin requires external circuits such as appropriate capacitors and
resistors.
See the IC specifications for a detailed description.
PECL outputs (VBB, DSYNCH, DSYNCL, CLKH, CLKL, CLK/2H, CLK/2L) are output constantly, but TTL
outputs (DSYNC, CLK, CLKN, CLK/2, CLK/2N, SEROUT, DIVOUT, UNLOCK) are controlled by the respective
control registers. Therefore, the enable/disable settings should be made in accordance with the application.
See the following pages for the setting method.
– 51 –
CXA3266Q
Jumper Wire Settings
S1, S2: These enable/disable HOLD (Pin 6). HOLD is active high, so the jumper wire should be connected to
S2 (HOLD = low) for normal use. When using HOLD, connect the jumper wire to S1 (HOLD = high).
(For the initial setting, the jumper wire is connected to S2.)
S3, S4: These enable/disable TLOAD (Pin 13). Connect the jumper wire to S4 (TLOAD = high) for normal use.
When using TLOAD, connect the jumper wire to S3 (TLOAD = low). (For the initial setting, the jumper
wire is connected to S4.)
S5, S6: These enable/disable CS (Pin 14). Connect the jumper wire to S6 (CS = high) for normal use. When
using Power Save, connect the jumper wire to S5 (CS = low). (For the initial setting, the jumper wire is
connected to S6.)
Supplied Program
This PWB has a control program that facilitates evaluation of the CXA3266Q. Operation methods and precautions
are as follows.
1) Compatible personal computers
Use an IBM PC/AT or compatible machine equipped with a 25-pin D-SUB parallel port (printer port). Also,
operating systems which support the program are MS-DOS 5.0 or newer and MS-Windows 3.1 or newer.
(When using Windows, start the program from the DOS window.)
2) Connection of the supplied cable
Connect the supplied cable to the parallel port of the personal computer and the DBUS1 connector of the
CXA3266Q-PWB.
D-SUB 25-pin parallel connector pin arrangement
1
13
14
Pin 2 : SCLK
Pin 3 : SDATA
Pin 4 : SENABLE
Pin 11 : SERIN
Pin 19 : GND
25
3) Connect the power cable and supply power to the CXA3266Q-PWB.
4) Start the program
A) Boot the personal computer and then shift to the directory containing the program.
B) Set MS-DOS to US mode. → US Return or Enter
C) Input the program name. → CXA3266Q Return or Enter → Move to the program screen.
– 52 –
CXA3266Q
5) Description of program screen
A) Setting of each function
When the program is started, the following initial screen is displayed.
A3266 PLL REGISTERS
Divisor 1672
Divider 2
Coarse Delay 00
Polarity
SYNC DSYNC
0
0
Fine Delay 0
Charge Pump 00
Power
SCAN SYNTH
ON
ON
PD
0
O/P Enable
DIVOUT
UNLOCK
ON
ON
DSYNC
ON
CLK2
ON
DSYNC Functions
DELAY
WIDTH
ON
00
HOLD
ON
BYPASS
ON
VCO Bypass
ON
NCLK2
ON
CLK1
ON
NCLK1
ON
Use arrow keys to select data bit. Press ENTER to toggle and load data.
Use Pg Up and Pg Dn to increment/decrement divisor and fine delay registers.
Press a to abort, s to scan registers
MIXED SIGNAL SYSTEMS AUG 1998
– 53 –
CXA3266Q
Divisor
This is used to input the frequency division ratio of the program counter. The value can be changed as
desired from 9 to 4111 by moving the cursor to the position of the number and pressing the Return or Enter
key. (Note: The operating range of the CXA3266Q is from 256 to 4096.) The value can also be incremented
or decremented by one step by pressing the Page Up or Page Down key, respectively.
The internal VCO has an oscillator frequency of 40 to 203MHz, so the output frequency and Divider (VCO
frequency divider) setting range are as follows.
40
Divider = 1
203
1/1
Divider
20
Divider = 2
100
1/2
Divider = 4
10
50
1/4
Divider = 8
5
25
1/8
50
100
150
200
O/P frequency [MHz]
Divider
This sets the VCO output frequency division ratio to 1/1, 1/2, 1/4 or 1/8. The frequency division ratio changes
repeatedly in the order of 1/1 → 1/2 → 1/4 → 1/8 → 1/1 each time the cursor is moved to the position of the
number and the Return or Enter key is pressed.
Coarse Delay
This is the DSYNC upper delay time setting. The value can be changed by moving the cursor to the position
of the number and pressing the Return or Enter key. The delay time variable range settings are "00" (2 CLK),
"01" (3 CLK), "10" (4 CLK) or "11" (5 CLK).
Fine Delay
This is the DSYNC lower delay time setting. The value can be changed by moving the cursor to the position
of the number and pressing the Return or Enter key. The value can also be incremented or decremented by
one step by pressing the Page Up or Page Down key, respectively. The delay time can be varied from 1/32
CLK to 64/32 CLK by setting "0" to "63", respectively.
Charge Pump
This is the charge pump circuit KI setting. The value can be changed by moving the cursor to the position of the
number and pressing the Return or Enter key. KI can be set to "00" (approximately 100µA), "01" (approximately
200µA), "10" (approximately 400µA) or "11" (approximately 800µA).
Polarity
These are the SYNC, DSYNC and PD (Phase Detector) polarity inversion settings, and should be set as
necessary such as when inverting the SYNC input and DSYNC output waveforms. The setting value "1" is
positive polarity, and "0" is negative polarity. These should normally all be set to "1". (Fix PD to "1" other than
during test mode.)
– 54 –
CXA3266Q
Power
SCAN:
This is the control register read setting. When this is ON, the control register serial data is
output from SEROUT (Pin 15). This should normally be set to OFF.
SYNTH:
This is the enable/disable setting for this IC. This should normally be set to ON.
VCO By-pass: This is set to OFF when testing the program counter. This should normally be set to ON.
O/P Enable
These are the enable/disable settings for each TTL output (DIVOUT, UNLOCK, DSYNC, CLK2, NCLK2,
CLK1 and NCLK1). Set to ON when performing evaluation using TTL output.
DSYNC Functions
DELAY:
When DIVOUT is output from DSYNC output, its delay is set. 4 CLK for OFF; 5 CLK for ON.
WIDTH:
When DIVOUT is output from DSYNC output, its pulse width is changed. Their settings are
1 CLK for "00", 2 CLK for "01", 4 CLK for "10", and 8 CLK for "11".
HOLD:
DSYNC output status is set during HOLD. Output OFF status for OFF (H or L fixed according
to DSYNC POL polarity); DSYNC or DIVOUT are output for ON.
BYPASS:
DSYNC/DIVOUT output switching from DSYNC output is performed. DSYNC is output for ON;
DIVOUT for OFF.
– 55 –
CXA3266Q
B) Description of readout mode
This program has a function (readout mode) that reads the contents written to the control registers from the
CXA3266Q SEROUT (Pin 15) and displays these contents on the screen. This function is described below.
1) Set SCAN to ON at the function setting screen.
2) Press the S key.
The following screen appears.
SCAN RESULT, CXA3266 PLL REGISTERS
Register
Register
Register
Register
Register
Register
Register
1
2
3
4
5
6
7
DIVREG1
DIVREG2
CENFREREG
DELAYREG
CPREG
TTLPOLREG
TESTPOWREG
00111000
0101
01
00100000
100110
11111111
111111
Press r to return to PLL REGISTERS MENU.
Press a to abort
MIXED SIGNAL SYSTEMS AUG 1998
This screen conforms to the Control Register Table listed in the CXA3266Q data sheet.
3) Press the R key to return to the original function setting screen.
C) Quit the program
Press the A key to quit the program.
– 56 –
CXA3266Q
AAAAAAAAAAAA
AAA
A
AAAAAAA
AAAAAAAAAAAA
AAAAA
AAA
AAAAAAA
AAAAAAAAAAAA
AAAAA
AAA
AAAAAAA
AAAAAAAAAAAA
AAAAA
AAA
AAA
AAAAAAA
AAAAA
Substrate Pattern (parts surface)
Substrate Pattern (solder surface)
– 57 –
CXA3266Q
VCO
VCOL
BNC3
VCC
VCOH
BNC2
GND
C21
33µ
+
BNC1
R1
PR10
VBB
CXA3266Q PWB
R19
R8
BNC4
SYNCH
R3
PR8
DSYNCL
R10
S1
S2
BNC5
SYNCL
R7
IC1
PR6
CLKL
R4
R11
R6
PR1
CLK/2L
PR4
UNLOCK
PR11
CLK/2N
PR12
CLK/2
PR13
CLKN
PR14
CLK
1C
21C
31C
4C
6C
81C
41C
02C
5C
C3
2C
01C
11C
7C
81C
51C
71C
61C
Silk Screen (solder surface)
– 58 –
PR5
CLK/2H
PR15
DSYNC
Silk Screen (parts surface)
91C
R5
R12
C9
C8
DBUS1
Control Register
R13
PR3
DIVOUT
PR7
CLKH
S3
S4
S5
S6
SYNC
PR2
SEROUT
PR9
DSYNCH
R9
R14
BNC6
R2
C21
33µ
VCC
5
1
GND
DBUS1
GND
SYNC
9
12
S3
SEROUT
DIVOUT
S6
15 16
CXA3266Q
19 20
C7
0.1µ
17 18
UNLOCK
PR2A
PR4A
PR3A
SEROUT DIVOUT UNLOCK
S4
S5
14
13
SDATA
11 SCLK
VCC
PWR2
GND
SYNCL
SYNCH
7
8
HOLD
VCO
5
6
VCOL
DSYNCH 34
VCOH
3
4
VBB 35
21
22 23
24
TTLGND 25
TTLVCC 26
IOGND 27
PECLVCC 28
CLK/2L 29
CLK/2H 30
CLKL 31
CLKH 32
DSYNCL 33
PECLVCC
IOGND
2
36
IOVCC
IRGND
1
IRVCC
10 SENABLE
PWR1
S2
BNC6
SYNC
S1
SYNCL
BNC5
SYNCH
BNC4
C2
0.1µ
VCOGND
DGND
VCO
38 37
40 39
42 41
43
44
45
48 47 46
C12
0.1µ
DVCC
BNC3
C3
0.1µ
PLLGND
CLK/2
VCOL
CLK/2N
BNC2
C6
0.1µ
C5
0.1µ
RC2
RC1
C4
0.1µ
IREF
C11
100p
VCOHGND
R19
3.0k
GND
VCOVCC
CLKN
VCOH
R18 C19
3.0k 0.068µ
C20
680p
PLLVCC
VOCLP
CLK
DSYNC
BNC1
Note) R1 to R7 are not mounted.
Control Register
IOGND
CS
– 59 –
TLOAD
PWB Circuit Diagram
GND
C9
0.1µ
C10
0.1µ
C8
0.1µ
VCC
C17
0.1µ
C16
0.1µ
C18
0.1µ
C15
0.1µ
C14
0.1µ
C13
0.1µ
C1
0.1µ
R6
R5
R7
R4
R3
R2
R1
VCC
R13 330
R12 330
R14 330
R11 330
R10 330
R9 330
R8 330
GND
CLK/2N
CLK/2
PR11A
CLKN
PR12A
CLK
PR13A
DSYNC
PR14A
PR15A
CLK/2L
PR1A
CLK/2H
PR5A
CLKL
PR6A
CLKH
PR7A
DSYNCL
PR8A
DSYNCH
PR9A
VBB
PR10A
CXA3266Q
CXA3266Q
Package Outline
Unit: mm
48PIN QFP (PLASTIC)
15.3 ± 0.4
+ 0.1
0.15 – 0.05
+ 0.4
12.0 – 0.1
0.15
36
25
24
13.5
37
48
+ 0.2
0.1 – 0.1
13
12
0.8
+ 0.15
0.3 – 0.1
0.24
M
0.9 ± 0.2
1
+ 0.35
2.2 – 0.15
PACKAGE STRUCTURE
SONY CODE
QFP-48P-L04
EIAJ CODE
QFP048-P-1212
JEDEC CODE
PACKAGE MATERIAL
EPOXY RESIN
LEAD TREATMENT
SOLDER / PALLADIUM
PLATING
LEAD MATERIAL
42/COPPER ALLOY
PACKAGE MASS
0.7g
NOTE : PALLADIUM PLATING
This product uses S-PdPPF (Sony Spec.-Palladium Pre-Plated Lead Frame).
– 60 –