9DBV0241
2-Output 1.8V PCIe Zero Delay/Fanout
Clock Buffer with Zo = 100ohms
DATASHEET
Description
Features/Benefits
The 9DBV0241 is a member of Renesas' 1.8V
Very-Low-Power (VLP) PCIe family. The device has 2 output
enables for clock management.
• LP-HCSL outputs with Zo = 100; saves 8 resistors
Recommended Application
•
•
1.8V PCIe Gen1–5 Zero-Delay/Fan-out Buffer (ZDB/FOB)
•
•
Output Features
• Two 1–200MHz Low-Power (LP) HCSL DIF pairs with
•
ZO = 100Ω
Key Specifications
•
•
•
•
•
•
DIF cycle-to-cycle jitter < 50ps
DIF output-to-output skew < 50ps
PCIe Gen5 CC additive phase jitter < 40fs RMS
12kHz–20MHz additive phase jitter = 156fs RMS at
156.25MHz (typical)
•
•
•
•
Block Diagram
vOE(1:0)#
y
2
CLK_IN
DIF1
CLK_IN#
^vHIBW_BYPM_LOBW#
^CKPWRGD_PD#
SDATA_3.3
SCLK_3.3
9DBV0241 R31DS0075EU0700 AUGUST 2, 2021
compared to standard HCSL outputs
35mW typical power consumption in PLL mode; reduced
thermal concerns
Spread Spectrum (SS) compatible; allows use of SS for
EMI reduction
OE# pins; support DIF power management
HCSL compatible differential input; can be driven by
common clock sources
SMBus-selectable features; optimize signal integrity to
application
• slew rate for each output
• differential output amplitude
Pin/software selectable PLL bandwidth and PLL Bypass;
optimize PLL to application
Outputs blocked until PLL is locked; clean system start-up
Device contains default configuration; SMBus interface not
required for device control
3.3V tolerant SMBus interface; works with legacy
controllers
Space saving 4 × 4mm 24-VFQFPN; minimal board space
SSCompatible
PLL
DIF0
CONTROL
LOGIC
1
©2021 Renesas Electronics Corporation
vOE1#
VDDO1.8
GND
^CKPWRGD_PD#
FB_DNC
Pin Configuration
^vHIBW_BYPM_LOBW#
9DBV0241 DATASHEET
24 23 22 21 20 19
FB_DNC# 1
VDDR1.8 2
CLK_IN 3
CLK_IN# 4
9DBV0241
epad is GND
GNDR 5
18 DIF1#
17 DIF1
16 VDDA1.8
15 GNDA
14 DIF0#
vOE0#
VDDO1.8
GND
9 10 11 12
SDATA_3.3
8
SCLK_3.3
13 DIF0
7
VDDDIG1.8
GNDDIG 6
24-pin VFQFPN, 4x4 mm, 0.5mm pitch
^ prefix indicates internal 120KOhm pull up resistor
^v prefix indicates internal 120KOhm pull up AND pull
down resistor (biased to VDD/2)
v prefix indicates internal 120KOhm pull down resistor
Power Management Table
SMBus
DIFx
OEx# Pin
True O/P
Comp. O/P
OEx bit
0
X
X
X
Low
Low
1
Running
0
X
Low
Low
1
Running
1
0
Running
Running
1
Running
1
1
Low
Low
1. If Bypass mode is selected, the PLL will be off, and outputs will be running.
CKPWRGD_PD#
CLK_IN
GND
5
6
10,21
15
Description
CLK_IN
(MHz)
100.00
50.00
125.00
Reserved
HiBW_BypM_LoBW#
0
M
1
Input receiver analog
Digital Power
DIF outputs
PLL Analog
MODE
PLL Lo BW
Bypass
PLL Hi BW
Byte1 [7:6]
Readback
00
01
11
Byte1 [4:3]
Control
00
01
11
SMBus Address
Frequency Select Table
FSEL
Byte3 [4:3]
00 (Default)
01
10
11
Off
On1
On1
On1
PLL Operating Mode
Power Connections
Pin Number
VDD
2
7
11,20
16
PLL
DIFx
(MHz)
CLK_IN
CLK_IN
CLK_IN
Reserved
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
+
Address
1101101
2
Read/Write bit
x
R31DS0075EU0700 AUGUST 2, 2021
9DBV0241 DATASHEET
Pin Descriptions
Pin#
Pin Name
Pin Description
Complement clock of differential feedback. The feedback output
1 FB_DNC#
DNC
and feedback input are connected internally on this pin. Do not
connect anything to this pin.
1.8V power for differential input clock (receiver). This VDD should
2 VDDR1.8
PWR
be treated as an Analog power rail and filtered appropriately.
3 CLK_IN
IN
True Input for differential reference clock.
4 CLK_IN#
IN
Complementary Input for differential reference clock.
5 GNDR
GND
Analog Ground pin for the differential input (receiver)
6 GNDDIG
GND
Ground pin for digital circuitry
7 VDDDIG1.8
PWR
1.8V digital power (dirty power)
8 SCLK_3.3
IN
Clock pin of SMBus circuitry, 3.3V tolerant.
9 SDATA_3.3
I/O
Data pin for SMBus circuitry, 3.3V tolerant.
10 GND
GND
Ground pin.
11 VDDO1.8
PWR
Power supply for outputs, nominally 1.8V.
Active low input for enabling DIF pair 0. This pin has an internal pull12 vOE0#
IN
down.
1 =disable outputs, 0 = enable outputs
13 DIF0
OUT
Differential true clock output
14 DIF0#
OUT
Differential Complementary clock output
15 GNDA
GND
Ground pin for the PLL core.
16 VDDA1.8
PWR
1.8V power for the PLL core.
17 DIF1
OUT
Differential true clock output
18 DIF1#
OUT
Differential Complementary clock output
Active low input for enabling DIF pair 1. This pin has an internal pull19 vOE1#
IN
down.
1 =disable outputs, 0 = enable outputs
20 VDDO1.8
PWR
Power supply for outputs, nominally 1.8V.
21 GND
GND
Ground pin.
Input notifies device to sample latched inputs and start up on first
high assertion. Low enters Power Down Mode, subsequent high
22 ^CKPWRGD_PD#
IN
assertions exit Power Down Mode. This pin has internal pull-up
resistor.
Trilevel input to select High BW, Bypass or Low BW mode. This
LATCHED
pin is biased to VDD/2 (Bypass mode) with internal pull up/pull down
23 ^vHIBW_BYPM_LOBW#
IN
resistors. See PLL Operating Mode Table for Details.
True clock of differential feedback. The feedback output and
24 FB_DNC
DNC
feedback input are connected internally on this pin. Do not connect
anything to this pin.
25 epad
GND
GND
NOTE: DNC indicates Do Not Connect anything to this pin.
R31DS0075EU0700 AUGUST 2, 2021
Type
3
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
9DBV0241 DATASHEET
Test Loads
Low-Power HCSL Differential Output Test Load
L
Rs
Rs
Zo=100ohm
2pF
2pF
Device
L = 5 inches
Alternate Terminations
The 9DBV family can easily drive LVPECL, LVDS, and CML logic. See “AN-891 Driving LVPECL, LVDS, and CML Logic with
"Universal" Low-Power HCSL Outputs” for details.
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
4
R31DS0075EU0700 AUGUST 2, 2021
9DBV0241 DATASHEET
Absolute Maximum Ratings
Stresses above the ratings listed below can cause permanent damage to the 9DBV0241. These ratings, which are standard
values for Renesas commercially rated parts, are stress ratings only. Functional operation of the device at these or any other
conditions above those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum
rating conditions for extended periods can affect product reliability. Electrical parameters are guaranteed only over the
recommended operating temperature range.
PARAMETER
SYMBOL
CONDITIONS
1.8V Supply Voltage
Input Voltage
Input High Voltage, SMBus
Storage Temperature
Junction Temperature
Input ESD protection
VDDxx
VIN
VIHSMB
Ts
Tj
ESD prot
Applies to all VDD pins
MIN
-0.5
-0.5
TYP
SMBus clock and data pins
-65
Human Body Model
MAX
2.5
VDD+0.5V
3.6V
150
125
2000
UNITS NOTES
V
V
V
°C
°C
V
1,2
1, 3
1
1
1
1
1
Guaranteed by design and characterization, not 100% tested in production.
2
Operation under these conditions is neither implied nor guaranteed.
3
Not to exceed 2.5V.
Electrical Characteristics–Clock Input Parameters
TA = TCOM or TIND; Supply Voltage per VDD of normal operation conditions, See Test Loads for Loading Conditions
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS NOTES
Input Common Mode
Voltage - DIF_IN
Input Swing - DIF_IN
VCOM
Common Mode Input Voltage
150
1000
mV
1
VSWING
Differential value
300
1450
mV
1
Input Slew Rate - DIF_IN
dv/dt
Measured differentially
0.4
8
V/ns
1,2
Input Leakage Current
IIN
VIN = V DD , VIN = GND
-5
5
uA
Input Duty Cycle
dtin
Measurement from differential waveform
45
55
%
1
Input Jitter - Cycle to Cycle
JDIFIn
Differential Measurement
0
125
ps
1
1
Guaranteed by design and characterization, not 100% tested in production.
2
Slew rate measured through +/-75mV window centered around differential zero
R31DS0075EU0700 AUGUST 2, 2021
5
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
9DBV0241 DATASHEET
Electrical Characteristics–Input/Supply/Common Parameters–Normal Operating
Conditions
TA = TAMB, Supply Voltages per normal operation conditions, See Test Loads for Loading Conditions
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
Supply Voltage
VDDx
Supply voltage for core and analog
1.7
1.8
1.9
V
Ambient Operating
Temperature
TAMB
Commercial range
0
25
70
°C
Industrial range
-40
25
85
°C
Input High Voltage
V IH
Single-ended inputs, except SMBus
0.75 V DD
V DD + 0.3
V
Input Mid Voltage
V IM
Single-ended tri-level inputs ('_tri' suffix)
0.4 V DD
0.6 V DD
V
Input Low Voltage
V IL
Single-ended inputs, except SMBus
-0.3
0.25 V DD
V
IIN
Single-ended inputs, V IN = GND, V IN = VDD
-5
5
uA
IINP
Single-ended inputs
V IN = 0 V; Inputs with internal pull-up resistors
-200
200
uA
Input Current
UNITS NOTES
V IN = VDD; Inputs with internal pull-down resistors
Input Frequency
Capacitance
Fiby p
Bypass mode
1
200
MHz
2
Fipll
100MHz PLL mode
60
100.00
140
MHz
2
Fipll
125MHz PLL mode
75
125.00
175
MHz
2
Fipll
50MHz PLL mode
30
50.00
65
MHz
2
CIN
Logic Inputs, except DIF_IN
1.5
5
pF
1
CINDIF_IN
DIF_IN differential clock inputs
1.5
2.7
pF
1,5
6
pF
1
1
ms
1,2
30
33
kHz
0
66
kHz
1
3
clocks
1,3
300
us
1,3
5
ns
2
2
Output pin capacitance
COUT
Clk Stabilization
Input SS Modulation
Frequency PCIe
Input SS Modulation
Frequency non-PCIe
TSTAB
fMODINPCIe
fMODIN
OE# Latency
t LATOE#
Tdrive_PD#
t DRVPD
Tfall
tF
From V DD Power-Up and after input clock
stabilization or de-assertion of PD# to 1st clock
Allowable Frequency for PCIe Applications
(Triangular Modulation)
Allowable Frequency for non-PCIe Applications
(Triangular Modulation)
DIF start after OE# assertion
DIF stop after OE# deassertion
DIF output enable after
PD# de-assertion
Fall time of single-ended control inputs
Trise
tR
Rise time of single-ended control inputs
5
ns
SMBus Input Low Voltage
V ILSMB
V DDSMB = 3.3V, see note 4 for V DDSMB < 3.3V
0.6
V
SMBus Input High Voltage
V IHSMB
V DDSMB = 3.3V, see note 5 for V DDSMB < 3.3V
3.6
V
SMBus Output Low Voltage
VOLSMB
At IPULLUP
0.4
V
SMBus Sink Current
IPULLUP
At V OL
4
V DDSMB
Bus Voltage
1.7
SCLK/SDATA Rise Time
tRSMB
(Max VIL - 0.15) to (Min VIH + 0.15)
1000
ns
1
SCLK/SDATA Fall Time
SMBus Operating
Frequency
tFSMB
(Min VIH + 0.15) to (Max VIL - 0.15)
300
ns
1
fMAXSMB
Maximum SMBus operating frequency
400
kHz
6
Guaranteed by design and characterization, not 100% tested in production.
2
Control input must be monotonic from 20% to 80% of input swing.
4
5
6
4
Nominal Bus Voltage
1
3
2.1
mA
3.6
V
Time from deassertion until outputs are >200 mV.
For VDDSMB < 3.3V, V IHSMB >= 0.8xV DDSMB.
DIF_IN input.
The differential input clock must be running for the SMBus to be active.
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
6
R31DS0075EU0700 AUGUST 2, 2021
9DBV0241 DATASHEET
Electrical Characteristics–DIF 0.7V Low Power HCSL Outputs
TA = TAMB, Supply Voltages per normal operation conditions, See Test Loads for Loading Conditions
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
Scope averaging on, fast setting
Scope averaging on, slow setting
Slew rate matching, Scope averaging on
1.6
1.1
Slew rate matching
dV/dt
dV/dt
dV/dt
2.8
2.0
7
4
3
20
Voltage High
VHIGH
660
736
850
Voltage Low
VLOW
Statistical measurement on single-ended signal
using oscilloscope math function. (Scope
averaging on)
-150
32
150
Max Voltage
Min Voltage
Crossing Voltage (abs)
Crossing Voltage (var)
Vmax
Vmin
Vcross_abs
Δ-Vcross
Measurement on single ended signal using
absolute value. (Scope averaging off)
Scope averaging off
Scope averaging off
769
21
391
13
1150
-300
250
Slew rate
1
2
MAX UNITS NOTES
550
140
V/ns
V/ns
%
1,2,3
1,2,3
1,2,4
7
mV
7
7
7
1,5
1,6
mV
mV
mV
Guaranteed by design and characterization, not 100% tested in production.
Measured from differential waveform
3
Slew rate is measured through the Vswing voltage range centered around differential 0V. This results in a +/-150mV window around
differential 0V.
4
Matching applies to rising edge rate for Clock and falling edge rate for Clock#. It is measured using a +/-75mV window centered on
the average cross point where Clock rising meets Clock# falling. The median cross point is used to calculate the voltage thresholds the
oscilloscope is to use for the edge rate calculations.
5
Vcross is defined as voltage where Clock = Clock# measured on a component test board and only applies to the differential rising
edge (i.e. Clock rising and Clock# falling).
6
The total variation of all Vcross measurements in any particular system. Note that this is a subset of Vcross_min/max (Vcross
absolute) allowed. The intent is to limit Vcross induced modulation by setting Δ-Vcross to be smaller than Vcross absolute.
7
At default SMBus settings.
Electrical Characteristics–Current Consumption
TA = TAMB, Supply Voltages per normal operation conditions, See Test Loads for Loading Conditions
PARAMETER
Operating Supply Current
Powerdown Current
SYMBOL
CONDITIONS
IDDA
VDDA+VDDR, PLL Mode, @100MHz
4.4
6
mA
1
IDD
VDD, All outputs active @100MHz
14.2
18
mA
1
IDDAPD
I DDPD
VDDA+VDDR, PLL Mode, @100MHz
0.01
0.9
1
1.4
mA
mA
1, 2
VDD, Outputs Low/Low
1
Guaranteed by design and characterization, not 100% tested in production.
2
Input clock stopped.
R31DS0075EU0700 AUGUST 2, 2021
7
MIN
TYP
MAX
UNITS
NOTES
1, 2
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
9DBV0241 DATASHEET
Electrical Characteristics–Output Duty Cycle, Jitter, Skew and PLL Characteristics
TA = TAMB, Supply Voltages per normal operation conditions, See Test Loads for Loading Conditions
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
NOTES
2
1
45
2.7
1.4
1.05
50
4
2
2
55
MHz
MHz
dB
%
1,5
1,5
1
1
PLL Bandwidth
BW
PLL Jitter Peaking
Duty Cycle
tJPEAK
t DC
-3dB point in High BW Mode
-3dB point in Low BW Mode
Peak Pass band Gain
Measured differentially, PLL Mode
Duty Cycle Distortion
t DCD
Measured differentially, Bypass Mode @100MHz
-1
-0.1
1
%
1,3
Jitter, Cycle to cycle
t jcyc-cyc
Bypass Mode, VT = 50%
PLL Mode VT = 50%
V T = 50%
PLL mode
Additive Jitter in Bypass Mode
2800
0
Skew, Output to Output
tpdBYP
tpdPLL
t sk3
3623
112
33
13
0.1
4500
200
50
50
5
ps
ps
ps
ps
ps
1
1,4
1,4
1,2
1,2
Skew, Input to Output
1
SYMBOL
Guaranteed by design and characterization, not 100% tested in production.
2
Measured from differential waveform
3
Duty cycle distortion is the difference in duty cycle between the output and the input clock when the device is operated in bypass mode.
4
All outputs at default slew rate
5
The MIN/TYP/MAX values of each BW setting track each other, i.e., Low BW MAX will never occur with Hi BW MIN.
Electrical Characteristics–Phase Jitter Parameters – 12kHz to 20MHz
TAMB = over the specified operating range. Supply Voltages per normal operation conditions. See Test Loads for loading conditions.
Parameter
Symbol
Conditions
Minimum
Typical
Maximum
12k-20M Additive Phase Jitter,
Fan-out Buffer M ode,
tjph12k-20MFOB
156
Fan-out Buffer M ode
SSC OFF, 156.25MHz
Notes:
1. Applies to all differential outputs, guaranteed by design and characterization. See Test Loads for measurement setup details.
2. 12kHz to 20M Hz brick wall filter.
2
Specification
Limit
Units
Notes
n/a
fs
(rms)
1, 2, 3
2
3. For RM S values additive jitter is calculated by solving for b where [b = sqrt(c - a )], a is rms input jitter and c is rms total jitter.
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
8
R31DS0075EU0700 AUGUST 2, 2021
9DBV0241 DATASHEET
Electrical Characteristics–Additive PCIe Phase Jitter for Fanout Buffer Mode[7]
T AMB = over the specified operating range. Supply Voltages per normal operation conditions. See Test Loads for loading conditions.
Parameter
Symbol
Conditions
Minimum Typical Maximum
Limit
tjphPCIeG1-CC
PCIe Gen 1 (2.5 GT/s)
1.7
3.0
86
PCIe Gen 2 Hi Band (5.0 GT/s)
0.033
0.049
3
PCIe Gen 2 Lo Band (5.0 GT/s)
0.122
0.199
3.1
tjphPCIeG3-CC
PCIe Gen 3 (8.0 GT/s)
0.059
0.098
1
tjphPCIeG4-CC
PCIe Gen 4 (16.0 GT/s)
0.059
0.098
0.5
tjphPCIeG5-CC
PCIe Gen 5 (32.0 GT/s)
0.023
0.038
0.15
tjphPCIeG1-SRIS
PCIe Gen 1 (2.5 GT/s)
0.175
0.038
n/a
tjphPCIeG2-SRIS
PCIe Gen 2 (5.0 GT/s)
0.156
0.275
n/a
tjphPCIeG3-SRIS
PCIe Gen 3 (8.0 GT/s)
0.041
0.247
n/a
tjphPCIeG4-SRIS
PCIe Gen 4 (16.0 GT/s)
0.043
0.064
n/a
tjphPCIeG5-SRIS
PCIe Gen 5 (32.0 GT/s)
0.036
0.066
n/a
tjphPCIeG2-CC
Additive PCIe Phase Jitter,
Fan-out Buffer Mode
(Common Clocked Architecture)
Additive PCIe Phase Jitter,
Fan-out Buffer Mode
(SRIS Architecture)
Units
ps
(p-p)
ps
(RMS)
ps
(RMS)
ps
(RMS)
ps
(RMS)
ps
(RMS)
ps
(RMS)
ps
(RMS)
ps
(RMS)
ps
(RMS)
ps
(RMS)
Notes
1, 2
1, 2
1, 2
1, 2
1, 2, 3, 4
1, 2, 3, 5
1, 2, 6
1, 2, 6
1, 2, 6
1, 2, 6
1, 2, 6
Notes:
1. The Refclk jitter is measured after applying the filter functions found in PCI Express Base Specification 5.0, Revision 1.0. See the Test Loads section of the data sheet
for the exact measurement setup. The total Ref Clk jitter limits for each data rate are listed for convenience. The worst case results for each data rate are summarized in
this table. If oscilloscope data is used, equipment noise is removed from all results.
2. Jitter measurements shall be made with a capture of at least 100,000 clock cycles captured by a real-time oscilloscope (RTO) with a sample rate of 20 GS/s or
greater. Broadband oscilloscope noise must be minimized in the measurement. The measured PP jitter is used (no extrapolation) for RTO measurements. Alternately Jitter measurements may be used with a Phase Noise Analyzer (PNA) extending (flat) and integrating and folding the frequency content up to an offset from the carrier
frequency of at least 200 M Hz (at 300 M Hz absolute frequency) below the Nyquist frequency. For PNA measurements for the 2.5 GT/s data rate, the RM S jitter is
converted to peak to peak jitter using a multiplication factor of 8.83. In the case where real-time oscilloscope and PNA measurements have both been done and produce
different results the RTO result must be used.
3. SSC spurs from the fundamental and harmonics are removed up to a cutoff frequency of 2 M Hz taking care to minimize removal of any non-SSC content.
4. Note that 0.7 ps RM S is to be used in channel simulations to account for additional noise in a real system.
5. Note that 0.25 ps RM S is to be used in channel simulations to account for additional noise in a real system.
6. The PCI Express Base Specification 5.0, Revision 1.0 provides the filters necessary to calculate SRIS jitter values, however, it does not provide specification limits,
hence the n/a in the Limit column. SRIS values are informative only. In general, a clock operating in an SRIS system must be twice as good as a clock operating in a
Common Clock system. For RM S values, twice as good is equivalent to dividing the CC value by 2. And additional consideration is the value for which to divide by 2.
The conservative approach is to divide the ref clock jitter limit, and the case can be made for dividing the channel simulation values by 2, if the ref clock is close to the Tx
clock input. An example for Gen4 is as follows. A "rule-of-thumb" SRIS limit would be either 0.5ps RM S/2 = 0.35ps RM S if the clock chip is far from the clock input, or
0.7ps RM S/ 2 = 0.5ps RM S if the clock chip is near the clock input..
7. Additive jitter for RM S values is calculated by solving for b where b
√ 𝑐2 𝑎2 , and a is rms input jitter and c is rms output jitter.
R31DS0075EU0700 AUGUST 2, 2021
9
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
9DBV0241 DATASHEET
Additive Phase Jitter Plot: 125M (12kHz to 20MHz)
RMS additve jitter: 251fs
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
10
R31DS0075EU0700 AUGUST 2, 2021
9DBV0241 DATASHEET
General SMBus Serial Interface Information
How to Write
•
•
Controller (host) sends a start bit
Controller (host) sends the write address
Renesas clock will acknowledge
Controller (host) sends the beginning byte location = N
Renesas clock will acknowledge
Controller (host) sends the byte count = X
Renesas clock will acknowledge
Controller (host) starts sending Byte N through Byte
N+X-1
Renesas clock will acknowledge each byte one at a time
Controller (host) sends a Stop bit
Index Block Write Operation
Controller (Host)
T
starT bit
Beginning Byte = N
ACK
Data Byte Count = X
WRite
ACK
Beginning Byte = N
ACK
RT
ACK
RD
Repeat starT
Slave Address
ReaD
X Byte
ACK
O
Data Byte Count=X
O
O
ACK
ACK
ACK
Beginning Byte N
Byte N + X - 1
P
Renesas
starT bit
WR
ACK
Beginning Byte N
O
Controller (Host)
Slave Address
ACK
O
Index Block Read Operation
T
WRite
O
•
•
•
Controller (host) will send a start bit
Controller (host) sends the write address
Renesas clock will acknowledge
Controller (host) sends the beginning byte location = N
Renesas clock will acknowledge
Controller (host) will send a separate start bit
Controller (host) sends the read address
Renesas clock will acknowledge
Renesas clock will send the data byte count = X
Renesas clock sends Byte N+X-1
Renesas clock sends Byte 0 through Byte X (if X(H) was
written to Byte 8)
Controller (host) will need to acknowledge each byte
Controller (host) will send a not acknowledge bit
Controller (host) will send a stop bit
Renesas (Slave/Receiver)
Slave Address
WR
•
•
•
•
•
•
•
•
•
•
•
stoP bit
X Byte
•
•
•
•
•
•
•
•
How to Read
O
O
Note: SMBus Address is 1101101x, where x is the
read/write bit.
R31DS0075EU0700 AUGUST 2, 2021
11
O
O
O
O
Byte N + X - 1
N
Not acknowledge
P
stoP bit
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
9DBV0241 DATASHEET
SMBus Table: Output Enable Register 1
Byte 0
Name
Control Function
Type
0
Reserved
Bit 7
Reserved
Bit 6
DIF OE1
Output Enable
RW
Low/Low
Bit 5
Reserved
Bit 4
DIF OE0
Output Enable
RW
Low/Low
Bit 3
Reserved
Bit 2
Reserved
Bit 1
Reserved
Bit 0
1. A low on these bits will override the OE# pin and force the differential output Low/Low
SMBus Table: PLL Operating Mode and Output Amplitude Control Register
Byte 1
Name
Control Function
Type
PLLMODERB1
PLL Mode Readback Bit 1
Bit 7
R
PLLMODERB0
PLL Mode Readback Bit 0
Bit 6
R
Bit 5
PLLMODE_SWCNTRL
Enable SW control of PLL Mode RW
PLLMODE1
PLL Mode Control Bit 1
Bit 4
PLLMODE0
PLL Mode Control Bit 0
Bit 3
Reserved
Bit 2
AMPLITUDE 1
Bit 1
Controls Output Amplitude
AMPLITUDE 0
Bit 0
1. B1[5] must be set to a 1 for these bits to have any effect on the part.
SMBus Table: DIF Slew Rate Control Register
Byte 2
Name
Control Function
Reserved
Bit 7
Reserved
Bit 6
SLEWRATESEL DIF1
Slew Rate Selection
Bit 5
Reserved
Bit 4
SLEWRATESEL DIF0
Slew Rate Selection
Bit 3
Reserved
Bit 2
Reserved
Bit 1
Reserved
Bit 0
SMBus Table: Frequency Select Control Register
Byte 3
Name
Control Function
Reserved
Bit 7
Reserved
Bit 6
Enable SW selection of
FREQ_SEL_EN
Bit 5
frequency
FSEL1
Freq. Select Bit 1
Bit 4
FSEL0
Freq. Select Bit 0
Bit 3
Reserved
Bit 2
Reserved
Bit 1
SLEWRATESEL FB
Adjust Slew Rate of FB
Bit 0
1. B3[5] must be set to a 1 for these bits to have any effect on the part.
0
1
Enabled
Enabled
1
See PLL Operating Mode Table
Values in B1[7:6]
set PLL Mode
Values in B1[4:3]
set PLL Mode
RW 1
RW 1
See PLL Operating Mode Table
RW
RW
00 = 0.6V
10= 0.8V
01 = 0.7V
11 = 0.9V
Type
0
1
RW
Slow setting
Fast setting
RW
Slow setting
Fast setting
Type
0
1
RW
SW frequency
change disabled
SW frequency
change enabled
RW 1
RW 1
RW
See Frequency Select Table
Slow setting
Fast setting
Default
1
1
1
1
1
1
1
1
Default
Latch
Latch
0
0
0
1
1
0
Default
1
1
1
1
1
1
1
1
Default
1
1
0
0
0
1
1
1
Byte 4 is Reserved and reads back 'hFF
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
12
R31DS0075EU0700 AUGUST 2, 2021
9DBV0241 DATASHEET
SMBus Table: Revision and Vendor ID Register
Byte 5
Name
Control Function
RID3
Bit 7
RID2
Bit 6
Revision ID
RID1
Bit 5
RID0
Bit 4
VID3
Bit 3
VID2
Bit 2
VENDOR ID
VID1
Bit 1
VID0
Bit 0
Type
R
R
R
R
R
R
R
R
SMBus Table: Device Type/Device ID
Byte 6
Name
Device Type1
Bit 7
Device Type0
Bit 6
Device ID5
Bit 5
Device ID4
Bit 4
Device ID3
Bit 3
Device ID2
Bit 2
Device ID1
Bit 1
Device ID0
Bit 0
Type
R
R
R
R
R
R
R
R
SMBus Table: Byte Count Register
Byte 7
Name
Bit 7
Bit 6
Bit 5
BC4
Bit 4
BC3
Bit 3
BC2
Bit 2
BC1
Bit 1
BC0
Bit 0
R31DS0075EU0700 AUGUST 2, 2021
Control Function
Device Type
Device ID
Control Function
Reserved
Reserved
Reserved
Byte Count Programming
13
Type
RW
RW
RW
RW
RW
0
1
A rev = 0000
0001 = IDT
0
1
00 = FGx, 01 = DBx,
10 = DMx, 11= Reserved
000100 binary or 02 hex
0
Default
0
0
0
0
0
0
0
1
Default
0
1
0
0
0
0
1
0
1
Default
0
0
0
0
Writing to this register will configure how
1
many bytes will be read back, default is
0
= 8 bytes.
0
0
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
9DBV0241 DATASHEET
Marking Diagrams
LOT
041AL
YYWW
LOT
041AIL
YYWW
Notes:
1. ‘LOT’ is the lot number.
2. ‘YYWW’ is the last two digits of the year and week that the part was assembled.
3. ‘L’ denotes RoHS compliant package.
4. ‘I’ denotes industrial temperature grade.
Thermal Characteristics
1
PARAMETER
SYMBOL
CONDITIONS
PKG
Thermal Resistance
θJC
θJb
θJA0
θJA1
θJA3
θJA5
Junction to Case
Junction to Base
Junction to Air, still air
Junction to Air, 1 m/s air flow
Junction to Air, 3 m/s air flow
Junction to Air, 5 m/s air flow
NLG20
NLG24
TYP
VALUE
62
5.4
50
43
39
38
UNITS
NOTES
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
1
1
1
1
1
1
ePad soldered to board
Package Outline Drawings
The package outline drawings are located at the end of this document and are accessible from the Renesas website. The
package information is the most current data available and is subject to change without revision of this document.
24-VFQFPN (NLG24P1)
Ordering Information
Part / Order Number Shipping Packaging
9DBV0241AKLF
Tubes
9DBV0241AKLFT
Tape and Reel
9DBV0241AKILF
Tubes
9DBV0241AKILFT
Tape and Reel
Package
24-pin VFQFPN
24-pin VFQFPN
24-pin VFQFPN
24-pin VFQFPN
Temperature
0 to +70° C
0 to +70° C
-40 to +85° C
-40 to +85° C
“LF” suffix to the part number are the Pb-Free configuration and are RoHS compliant.
“A” is the device revision designator (will not correlate with the datasheet revision).
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
14
R31DS0075EU0700 AUGUST 2, 2021
9DBV0241 DATASHEET
Revision History
Revision Date
August 13, 2012
September 6, 2014
August 10, 2015
Description
1. Updated electrical characteristics tables.
2. Move to final.
1. Changed VIH min. from 0.65*VDD to 0.75*VDD
2. Changed VIL max. from 0.35*VDD to 0.25*VDD
3. Added missing mid-level input voltage spec (VIM) of 0.4*VDD to 0.6*VDD.
4. Changed Shipping Packaging from "Trays" to Tubes".
5. Reformatted to new template
1. Updated front page text for family consistency
2. Updated block diagram for family consistency
3. Updated pin configuration to indicate that paddle is ground
4. Added epad as pin 25 to pin descritptions
5. Replaced "Driving LVDS" with "Alternate Terminations", adding reference to AN-891.
6. Updated "Clock Input Parameters Table" correcting inconsistency with PCIe SIG specifications.
7. Widened allowable input frequency at each PLL mode frequency.
8. Updated phase jitter parameters with 12k-20M additive phase jitter and added additive phase jitter graph.
9. Updated NLG24 package drawing with actual package info instead of generic drawing.
September 11, 2015 1. Corrected block diagram from clock generator to ZDB buffer
1. Minor typographical corrections throughout the data sheet
2. Updated test load diagram to generic diagram. Length of test load listed outside the drawing.
3. Minor updates to electrical tables for formatting. Removed Schmitt trigger info and output high/low voltage
specifications for single-ended outputs, since this part does not have any.
4. "Low-Power HCSL Outputs" table: corrected inversion of slew rate setting with specifications. Changed
November 4, 2015 reference from 2 V/ns and 3 V/ns to slow setting and fast setting. Also change references in SMBus
Bytes[3:2]
5. "Low-Power HCSL Outputs" table: Removed Vswing parameter since this is an input parameter and is
covered in "Clock Input Parameters" Table.
6. Reduced current consumption limits.
7. Minor updates to other electrical tables.
1. Updated max frequency of 100MHz PLL mode to 140MHz
April 22, 2016
2. Updated max frequency of 125MHz PLL mode to 175MHz
3. Updated max frequency of 50MHz PLL mode to 65MHz
1. Updated document title.
2. Updated Recommended Applications.
August 2, 2021
3. Updated Key Specifications.
4. Updated Package Outline Drawings section.
5. Updated Phase Jitter tables.
R31DS0075EU0700 AUGUST 2, 2021
15
2-OUTPUT 1.8V PCIE ZERO DELAY/FANOUT CLOCK BUFFER WITH ZO = 100OHMS
24-VFQFPN, Package Outline Drawing
4.0 x 4.0 x 0.90 mm Body,0.50mm Pitch,Epad 2.45 x 2.45 mm
NLG24P1, PSC-4192-01, Rev 02, Page 1
© Integrated Device Technology, Inc.
24-VFQFPN, Package Outline Drawing
4.0 x 4.0 x 0.90 mm Body,0.50mm Pitch,Epad 2.45 x 2.45 mm
NLG24P1, PSC-4192-01, Rev 02, Page 2
Package Revision History
© Integrated Device Technology, Inc.
Description
Date Created
Rev No.
Sept 9, 2016
Rev 01
Sept 13, 2018
Rev 02 New Format, Recalculate Land Pattern Change QFN to VFQFPN
Add Chamfer on Epad
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