ALTERA EP3C10

1. Cyclone III Device Data Sheet
CIII52001-3.3
This chapter describes the electric characteristics, switching characteristics, and I/O
timing for Cyclone® III devices. A glossary is also included for your reference.
Electrical Characteristics
The following sections provide information about the absolute maximum ratings,
recommended operating conditions, DC characteristics, and other specifications for
Cyclone III devices.
Operating Conditions
When Cyclone III devices are implemented in a system, they are rated according to a
set of defined parameters. To maintain the highest possible performance and
reliability of Cyclone III devices, system designers must consider the operating
requirements in this document. Cyclone III devices are offered in commercial,
industrial, and automotive grades. Commercial devices are offered in –6 (fastest), –7,
and –8 speed grades. Industrial and automotive devices are offered only in –7 speed
grade.
1
In this chapter, a prefix associated with the operating temperature range is attached to
the speed grades; commercial with “C” prefix, industrial with “I” prefix, and
automotive with “A” prefix. Commercial devices are therefore indicated as C6, C7,
and C8 per respective speed grades. Industrial and automotive devices are indicated
as I7 and A7, respectively.
Absolute Maximum Ratings
Absolute maximum ratings define the maximum operating conditions for Cyclone III
devices. The values are based on experiments conducted with the device and
theoretical modeling of breakdown and damage mechanisms. The functional
operation of the device is not implied at these conditions. Table 1–1 lists the absolute
maximum ratings for Cyclone III devices.
1
Conditions beyond those listed in Table 1–1 cause permanent damage to the device.
Additionally, device operation at the absolute maximum ratings for extended periods
of time has adverse effects on the device.
Table 1–1. Cyclone III Devices Absolute Maximum Ratings
Symbol
© January 2010
Parameter
(Note 1)
(Part 1 of 2)
Min
Max
Unit
VC CINT
Supply voltage for internal logic
–0.5
1.8
V
VC CIO
Supply voltage for output buffers
–0.5
3.9
V
VC CA
Supply voltage (analog) for phase-locked loop
(PLL) regulator
–0.5
3.75
V
VC CD_P LL
Supply voltage (digital) for PLL
–0.5
1.8
V
VI
DC input voltage
–0.5
3.95
V
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–2
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
Table 1–1. Cyclone III Devices Absolute Maximum Ratings
Symbol
Parameter
(Note 1)
(Part 2 of 2)
Min
Max
Unit
IOUT
DC output current, per pin
–25
40
mA
VES DHBM
Electrostatic discharge voltage using the human
body model
—
±2000
V
VES DCDM
Electrostatic discharge voltage using the
charged device model
—
±500
V
TS TG
Storage temperature
–65
150
°C
TJ
Operating junction temperature
–40
125
°C
Note to Table 1–1:
(1) Supply voltage specifications apply to voltage readings taken at the device pins with respect to ground, not at the
power supply.
Maximum Allowed Overshoot or Undershoot Voltage
During transitions, input signals may overshoot to the voltage listed in Table 1–2 and
undershoot to –2.0 V for a magnitude of currents less than 100 mA and for periods
shorter than 20 ns. Table 1–2 lists the maximum allowed input overshoot voltage and
the duration of the overshoot voltage as a percentage over the lifetime of the device.
The maximum allowed overshoot duration is specified as percentage of high-time
over the lifetime of the device.
1
A DC signal is equivalent to 100% duty cycle. For example, a signal that overshoots to
4.2 V can only be at 4.2 V for 10.74% over the lifetime of the device; for device lifetime
of 10 years, this amounts to 10.74/10ths of a year.
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
1–3
Table 1–2. Cyclone III Devices Maximum Allowed Overshoot During Transitions over a 10-Year Time
Frame
(Note 1)
Symbol
Vi
Parameter
AC Input
Voltage
Condition
Overshoot Duration as % of High Time
Unit
VI = 3.95 V
100
%
VI = 4.0 V
95.67
%
VI = 4.05 V
55.24
%
VI = 4.10 V
31.97
%
VI = 4.15 V
18.52
%
VI = 4.20 V
10.74
%
VI = 4.25 V
6.23
%
VI = 4.30 V
3.62
%
VI = 4.35 V
2.1
%
VI = 4.40 V
1.22
%
VI = 4.45 V
0.71
%
VI = 4.50 V
0.41
%
VI = 4.60 V
0.14
%
VI = 4.70 V
0.047
%
Note to Table 1–2:
(1) Figure 1–1 shows the methodology to determine the overshoot duration. In the example in Figure 1–1, overshoot
voltage is shown in red and is present on the input pin of the Cyclone III device at over 4.1 V but below 4.2 V. From
Table 1–1, for an overshoot of 4.1 V, the percentage of high time for the overshoot can be as high as 31.97% over
a 10-year period. Percentage of high time is calculated as ([delta T]/T) × 100. This 10-year period assumes the
device is always turned on with 100% I/O toggle rate and 50% duty cycle signal. For lower I/O toggle rates and
situations in which the device is in an idle state, lifetimes are increased.
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–4
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
Figure 1–1 shows the methodology to determine the overshoot duration.
Figure 1–1. Cyclone III Devices Overshoot Duration
4.2 V
4.1 V
3.3 V
ΔT
T
Recommended Operating Conditions
This section lists the functional operation limits for AC and DC parameters for
Cyclone III devices. The steady-state voltage and current values expected from
Cyclone III devices are provided in Table 1–3. All supplies must be strictly monotonic
without plateaus.
Table 1–3. Cyclone III Devices Recommended Operating Conditions
Symbol
VC CINT (3)
VC CIO (3), (4)
VC CA (3)
Parameter
(Note 1) , (2) (Part 1 of 2)
Conditions
Min
Typ
Max
Unit
Supply voltage for internal logic
—
1.15
1.2
1.25
V
Supply voltage for output buffers, 3.3-V
operation
—
3.135
3.3
3.465
V
Supply voltage for output buffers, 3.0-V
operation
—
2.85
3
3.15
V
Supply voltage for output buffers, 2.5-V
operation
—
2.375
2.5
2.625
V
Supply voltage for output buffers, 1.8-V
operation
—
1.71
1.8
1.89
V
Supply voltage for output buffers, 1.5-V
operation
—
1.425
1.5
1.575
V
Supply voltage for output buffers, 1.2-V
operation
—
1.14
1.2
1.26
V
Supply (analog) voltage for PLL
regulator
—
2.375
2.5
2.625
V
VC CD_P LL (3)
Supply (digital) voltage for PLL
—
1.15
1.2
1.25
V
VI
Input voltage
—
–0.5
—
3.6
V
VO
Output voltage
—
0
—
VCC IO
V
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
1–5
Table 1–3. Cyclone III Devices Recommended Operating Conditions
Symbol
TJ
Parameter
Operating junction temperature
tRAM P
Power supply ramp time
Conditions
Min
Typ
Max
Unit
For commercial use
0
—
85
°C
For industrial use
–40
—
100
°C
For extended temperature
(5)
–40
—
125
°C
For automotive use
–40
—
125
°C
Standard power-on reset
(POR) (6)
50 µs
—
50 ms
—
Fast POR (7)
50 µs
—
3 ms
—
—
—
—
10
mA
Magnitude of DC current across
PCI-clamp diode when enabled
IDiode
(Note 1) , (2) (Part 2 of 2)
Notes to Table 1–3:
(1) VCC IO for all I/O banks must be powered up during device operation. All VCCA pins must be powered to 2.5 V (even when PLLs are not used), and
must be powered up and powered down at the same time.
(2) VCC D_P LL must always be connected to VCCINT through a decoupling capacitor and ferrite bead.
(3) The VCC must rise monotonically.
(4) All input buffers are powered by the V C CIO supply.
(5) The I7 devices support extended operating junction temperature up to 125°C (usual range is –40°C to 100°C). When using I7 devices at the
extended junction temperature ranging from –40°C to 125°C, select C8 as the target device when designing in the Quartus® II software. The I7
devices meet all C8 timing specifications when I7 devices operate beyond 100°C and up to 125°C.
(6) POR time for Standard POR ranges between 50–200 ms. Each individual power supply should reach the recommended operating range within
50 ms.
(7) POR time for Fast POR ranges between 3–9 ms. Each individual power supply should reach the recommended operating range within 3 ms.
DC Characteristics
This section lists the I/O leakage current, pin capacitance, on-chip termination (OCT)
tolerance, and bus hold specifications for Cyclone III devices.
Supply Current
Standby current is the current the device draws after the device is configured with no
inputs or outputs toggling and no activity in the device. Use the Excel-based early
power estimator (EPE) to get the supply current estimates for your design because
these currents vary largely with the resources used. Table 1–4 lists I/O pin leakage
current for Cyclone III devices.
Table 1–4. Cyclone III Devices I/O Pin Leakage Current (Note 1) , (2)
Symbol
Parameter
Conditions
(Part 1 of 2)
Device
Min
Typ
Max
Unit
II
Input pin leakage current
VI = 0 V to VCCIOMAX
—
–10
—
10
μA
IOZ
Tristated I/O pin leakage
current
VO = 0 V to VCCIOMAX
—
–10
—
10
μA
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–6
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
Table 1–4. Cyclone III Devices I/O Pin Leakage Current (Note 1) , (2)
Symbol
ICC INT0
ICC A0
ICC D_PLL0
ICC IO0
Parameter
VCC INT supply current
(standby)
VCC A supply current
(standby)
VCC D_PLL supply current
(standby)
VCC IO supply current
(standby)
Conditions
VI = ground, no
load, no toggling
inputs, TJ = 25°C
VI = ground, no load,
no toggling inputs,
TJ = 25°C
VI = ground, no load,
no toggling inputs,
TJ = 25°C
VI = ground, no load,
no toggling inputs,
TJ = 25°C
(Part 2 of 2)
Device
Min
Typ
Max
EP3C5
—
1.7
mA
EP3C10
—
1.7
mA
EP3C16
—
3.0
mA
EP3C25
—
3.5
EP3C40
—
4.3
EP3C55
—
5.2
mA
EP3C80
—
6.5
mA
EP3C120
—
8.4
mA
EP3C5
—
11.3
mA
EP3C10
—
11.3
mA
EP3C16
—
11.4
mA
EP3C25
—
18.4
EP3C40
—
18.6
EP3C55
—
18.7
mA
EP3C80
—
18.9
mA
EP3C120
—
19.2
mA
EP3C5
—
4.1
mA
EP3C10
—
4.1
mA
EP3C16
—
8.2
mA
EP3C25
—
8.2
EP3C40
—
8.2
EP3C55
—
8.2
mA
EP3C80
—
8.2
mA
EP3C120
—
8.2
mA
EP3C5
—
0.6
mA
EP3C10
—
0.6
mA
EP3C16
—
0.9
mA
EP3C25
—
0.9
EP3C40
—
1.3
EP3C55
—
1.3
mA
EP3C80
—
1.3
mA
EP3C120
—
1.2
mA
(3)
(3)
(3)
(3)
Unit
mA
mA
mA
mA
mA
mA
mA
mA
Notes to Table 1–4:
(1) This value is specified for normal device operation. The value varies during device power-up. This applies for all V C CIO settings (3.3, 3.0, 2.5, 1.8,
1.5, and 1.2 V).
(2) 10 μA I/O leakage current limit is applicable when the internal clamping diode is off. A higher current can be the observed when the diode is on.
(3) Maximum values depend on the actual TJ and design utilization. For maximum values, refer to the Excel-based PowerPlay EPE
(www.altera.com/support/devices/estimator/cy3-estimator/cy3-power_estimator.html) or the Quartus II PowerPlay power analyzer feature. For
more information about power consumption, refer to “Power Consumption” on page 1–14 for more information.
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
1–7
Bus Hold
Bus hold retains the last valid logic state after the source driving it either enters the
high impedance state or is removed. Each I/O pin has an option to enable bus hold in
user mode. Bus hold is always disabled in configuration mode.
Table 1–5 lists bus hold specifications for Cyclone III devices.
Table 1–5. Cyclone III Devices Bus Hold Parameter
(Note 1)
VCC IO (V)
Parameter
Condition
1.2
1.5
1.8
2.5
3.0
3.3
Unit
Min
Max
Min
Max
Min
Max
Min
Max
Min
Max
Min
Max
Bus-hold
low,
sustaining
current
VIN > VIL
(maximum)
8
—
12
—
30
—
50
—
70
—
70
—
μA
Bus-hold
high,
sustaining
current
VIN < VIL
(minimum)
–8
—
–12
—
–30
—
–50
—
–70
—
–70
—
μA
Bus-hold
low,
overdrive
current
0 V < VIN < VCC IO
—
125
—
175
—
200
—
300
—
500
—
500
μA
Bus-hold
high,
overdrive
current
0 V < VIN < VCC IO
—
–125
—
–175
—
–200
—
–300
—
–500
—
–500
μA
—
0.3
0.9
0.68
1.07
0.7
1.7
0.8
2
0.8
2
V
Bus-hold trip
point
0.375 1.125
Note to Table 1–5:
(1) The bus-hold trip points are based on calculated input voltages from the JEDEC standard.
OCT Specifications
Table 1–6 lists the variation of OCT without calibration across process, temperature,
and voltage.
Table 1–6. Cyclone III Devices Series OCT without Calibration Specifications
Resistance Tolerance
Description
Series OCT without
calibration
VCCIO (V)
Commercial
Max
Industrial and Automotive
Max
Unit
3.0
±30
±40
%
2.5
±30
±40
%
1.8
+40
±50
%
1.5
+50
±50
%
1.2
+50
±50
%
OCT calibration is automatically performed at device power-up for OCT enabled
I/Os.
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–8
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
Table 1–7 lists the OCT calibration accuracy at device power-up.
Table 1–7. Cyclone III Devices Series OCT with Calibration at Device Power-Up Specifications
Calibration Accuracy
Description
Series OCT with
calibration at device
power-up
VCCIO (V)
Industrial and Automotive
Max
Unit
Commercial Max
3.0
±10
±10
%
2.5
±10
±10
%
1.8
±10
±10
%
1.5
±10
±10
%
1.2
±10
±10
%
The OCT resistance may vary with the variation of temperature and voltage after
calibration at device power-up. Use Table 1–8 and Equation 1–1 to determine the final
OCT resistance considering the variations after calibration at device power-up.
Table 1–8 lists the change percentage of the OCT resistance with voltage and
temperature.
Table 1–8. Cyclone III Devices OCT Variation After Calibration at Device Power-Up
Nominal Voltage
dR/dT (%/°C)
dR/dV (%/mV)
3.0
0.262
–0.026
2.5
0.234
–0.039
1.8
0.219
–0.086
1.5
0.199
–0.136
1.2
0.161
–0.288
Equation 1–1. (Note 1), (2), (3), (4), (5), (6)
ΔRV = (V2 – V1) × 1000 × dR/dV ––––– (7)
ΔRT = (T2 – T1) × dR/dT ––––– (8)
For ΔRx < 0; MFx = 1/ (|ΔRx|/100 + 1) ––––– (9)
For ΔRx > 0; MFx = ΔRx /100 + 1 ––––– (10)
MF = MFV × MFT ––––– (11)
Rfinal = Rinitia l × MF ––––– (12)
Notes to Equation 1–1:
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)
(10)
(11)
(12)
T2 is the final temperature.
T1 is the initial temperature.
MF is multiplication factor.
Rfinal is final resistance.
Rinitial is initial resistance.
Subscript × refers to both V and T.
ΔRV is variation of resistance with voltage.
ΔRT is variation of resistance with temperature.
dR/dT is the change percentage of resistance with temperature after calibration at device power-up.
dR/dV is the change percentage of resistance with voltage after calibration at device power-up.
V2 is final voltage.
V1 is the initial voltage.
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
1–9
Example 1–1 shows you the example to calculate the change of 50 Ω I/O impedance
from 25°C at 3.0 V to 85°C at 3.15 V:
Example 1–1.
ΔRV = (3.15 – 3) × 1000 × –0.026 = –3.83
ΔRT = (85 – 25) × 0.262 = 15.72
Because ΔRV is negative,
MF V = 1 / (3.83/100 + 1) = 0.963
Because ΔRT is positive,
MFT = 15.72/100 + 1 = 1.157
MF = 0.963 × 1.157 = 1.114
Rfinal = 50 × 1.114 = 55.71 Ω
Pin Capacitance
Table 1–9 lists the pin capacitance for Cyclone III devices.
Table 1–9. Cyclone III Devices Pin Capacitance
Symbol
Parameter
Typical –
QFP
Typical –
FBGA
Unit
CIOTB
Input capacitance on top/bottom I/O pins
7
6
pF
CIOLR
Input capacitance on left/right I/O pins
7
5
pF
CLV DSLR
Input capacitance on left/right I/O pins with dedicated
LVDS output
8
7
pF
CV REFLR (1)
Input capacitance on left/right dual-purpose VREF pin
when used as VREF or user I/O pin
21
21
pF
CV REFTB (1)
Input capacitance on top/bottom dual-purpose VREF pin
when used as VREF or user I/O pin
23 (2)
23 (2)
pF
CC LKTB
Input capacitance on top/bottom dedicated clock input
pins
7
6
pF
CC LKLR
Input capacitance on left/right dedicated clock input pins
6
5
pF
Notes to Table 1–9:
(1) When VREF pin is used as regular input or output, a reduced performance of toggle rate and tC O is expected due to
higher pin capacitance.
(2) CVREFTB for EP3C25 is 30 pF.
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–10
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
Internal Weak Pull-Up and Weak Pull-Down Resistor
Table 1–10 lists the weak pull-up and pull-down resistor values for Cyclone III
devices.
Table 1–10. Cyclone III Devices Internal Weak Pull-Up and Weak Pull-Down Resistor
Symbol
R_P U
R_P D
Parameter
(Note 1)
Conditions
Value of I/O pin pull-up resistor before
and during configuration, as well as
user mode if the programmable
pull-up resistor option is enabled
Value of I/O pin pull-down resistor
before and during configuration
Min
Typ
Max
Unit
VCC IO = 3.3 V ± 5% (2), (3)
7
25
41
kΩ
VCC IO = 3.0 V ± 5% (2), (3)
7
28
47
kΩ
VCC IO = 2.5 V ± 5% (2), (3)
8
35
61
kΩ
VCC IO = 1.8 V ± 5% (2), (3)
10
57
108
kΩ
VCC IO = 1.5 V ± 5% (2), (3)
13
82
163
kΩ
VCC IO = 1.2 V ± 5% (2), (3)
19
143
351
kΩ
VCC IO = 3.3 V ± 5% (4)
6
19
30
kΩ
VCC IO = 3.0 V ± 5% (4)
6
22
36
kΩ
VCC IO = 2.5 V ± 5% (4)
6
25
43
kΩ
VCC IO = 1.8 V ± 5% (4)
7
35
71
kΩ
VCC IO = 1.5 V ± 5% (4)
8
50
112
kΩ
Notes to Table 1–10:
(1) All I/O pins have an option to enable weak pull-up except configuration, test, and JTAG pin. Weak pull-down feature is only available for JTAG
TCK.
(2) Pin pull-up resistance values may be lower if an external source drives the pin higher than VCCIO .
(3) R_P U = (VCCIO – VI )/I R_PU
Minimum condition: –40°C; VCC IO = VC C + 5%, VI = VCC + 5% – 50 mV;
Typical condition: 25°C; VCC IO = VC C, VI = 0 V;
Maximum condition: 125°C; VCCIO = VCC – 5% , VI = 0 V; in which VI refers to the input voltage at the I/O pin.
(4) R_P D = VI /I R_PD
Minimum condition: –40°C; VCC IO = VC C + 5%, VI = 50 mV;
Typical condition: 25°C; VCC IO = VC C, VI = VCC – 5% ;
Maximum condition: 125°C; VCCIO = VCC – 5% , VI = VC C – 5% ; in which VI refers to the input voltage at the I/O pin.
Hot Socketing
Table 1–11 lists the hot-socketing specifications for Cyclone III devices.
Table 1–11. Cyclone III Devices Hot-Socketing Specifications
Symbol
Parameter
Maximum
IIOPIN(DC )
DC current per I/O pin
300 μA
IIOPIN(A C)
AC current per I/O pin
8 mA (1)
Note to Table 1–11:
(1) The I/O ramp rate is 10 ns or more. For ramp rates faster than 10 ns, |IIOPIN| = C
dv/dt, in which C is I/O pin capacitance and dv/dt is the slew rate.
Schmitt Trigger Input
Cyclone III devices support Schmitt trigger input on TDI, TMS, TCK, nSTATUS,
nCONFIG, nCE, CONF_DONE, and DCLK pins. A Schmitt trigger feature introduces
hysteresis to the input signal for improved noise immunity, especially for signal with
slow edge rate. Table 1–12 lists the hysteresis specifications across supported VCCIO
range for Schmitt trigger inputs in Cyclone III devices.
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
1–11
Table 1–12. Hysteresis Specifications for Schmitt Trigger Input in Cyclone III Devices
Symbol
Parameter
Hysteresis for Schmitt trigger
input
VS CHM ITT
Conditions
Minimum
Typical
Maximum
Unit
VCC IO = 3.3 V
200
—
—
mV
VCC IO = 2.5 V
200
—
—
mV
VCC IO = 1.8 V
140
—
—
mV
VCC IO = 1.5 V
110
—
—
mV
I/O Standard Specifications
The following tables list input voltage sensitivities (V IH and VIL), output voltage (VOH
and VOL), and current drive characteristics (IOH and IOL) for various I/O standards
supported by Cyclone III devices. Table 1–13 through Table 1–18 provide the I/O
standard specifications for Cyclone III devices.
Table 1–13. Cyclone III Devices Single-Ended I/O Standard Specifications
VCC IO (V)
VIL (V)
(Note 1), (2)
VIH (V)
VOL (V)
VO H (V)
Min
IO L
(mA)
IO H
(mA)
I/O Standard
Min
Typ
Max
Min
Max
Min
Max
Max
3.3-V LVTTL (3)
3.135
3.3
3.465
—
0.8
1.7
3.6
0.45
2.4
4
–4
3.3-V LVCMOS (3)
3.135
3.3
3.465
—
0.8
1.7
3.6
0.2
VC CIO – 0.2
2
–2
3.0-V LVTTL (3)
2.85
3.0
3.15
–0.3
0.8
1.7
VC CIO + 0.3
0.45
2.4
4
–4
3.0-V LVCMOS (3)
2.85
3.0
3.15
–0.3
0.8
1.7
VC CIO + 0.3
0.2
VC CIO – 0.2
0.1
–0.1
2.5-V LVTTL and
LVCMOS (3)
2.375
2.5
2.625
–0.3
0.7
1.7
VC CIO + 0.3
0.4
2.0
1
–1
1.8-V LVTTL and
LVCMOS
1.71
1.8
1.89
–0.3
0.35 *
VCCIO
0.65 *
VCC IO
2.25
0.45
VCC IO – 0.45
2
–2
1.5-V LVCMOS
1.425
1.5
1.575
–0.3
0.35 *
VCCIO
0.65 *
VCC IO
VC CIO + 0.3
0.25 * VC CIO 0.75 * VCC IO
2
–2
1.2-V LVCMOS
1.14
1.2
1.26
–0.3
0.35 *
VCCIO
0.65 *
VCC IO
VC CIO + 0.3
0.25 * VC CIO 0.75 * VCC IO
2
–2
3.0-V PCI
2.85
3.0
3.15
—
0.3 *
VCCIO
0.5 *
VCC IO
VC CIO + 0.3
0.1 * VCC IO
0.9 * VC CIO
1.5
–0.5
3.0-V PCI-X
2.85
3.0
3.15
—
0.35*
VCCIO
0.5 *
VCC IO
VC CIO + 0.3
0.1 * VCC IO
0.9 * VC CIO
1.5
–0.5
Notes to Table 1–13:
(1) For voltage referenced receiver input waveform and explanation of terms used in Table 1–13, refer to “Single-ended Voltage referenced I/O Standard”
in “Glossary” on page 1–27.
(2) AC load CL = 10 pF.
(3) For more detail about interfacing Cyclone III devices with 3.3/3.0/2.5-V LVTTL/LVCMOS I/O standards, refer to AN 447: Interfacing Cyclone III
Devices with 3.3/3.0/2.5-V LVTTL and LVCMOS I/O Systems.
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–12
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
Table 1–14. Cyclone III Devices Single-Ended SSTL and HSTL I/O Reference Voltage Specifications
I/O
Standard
VCC IO (V)
VREF (V)
(Note 1)
VTT (V) (Note 2)
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
SSTL-2
Class I, II
2.375
2.5
2.625
1.19
1.25
1.31
VREF – 0.04
VREF
VREF + 0.04
SSTL-18
Class I, II
1.7
1.8
1.9
0.833
0.9
0.969
VREF – 0.04
VREF
VREF + 0.04
HSTL-18
Class I, II
1.71
1.8
1.89
0.85
0.9
0.95
0.85
0.9
0.95
HSTL-15
Class I, II
1.425
1.5
1.575
0.71
0.75
0.79
0.71
0.75
0.79
HSTL-12
Class I, II
1.14
1.2
1.26
—
0.5 * VCC IO
—
0.48 * VCC IO (3)
0.5 * VC CIO (3)
0.52 * VCC IO (3)
0.47 * VCC IO (4)
0.5 * VC CIO (4)
0.53 * VCC IO (4)
Notes to Table 1–14:
(1)
(2)
(3)
(4)
For an explanation of terms used in Table 1–14, refer to “Glossary” on page 1–27.
VTT of transmitting device must track VREF of the receiving device.
Value shown refers to DC input reference voltage, VREF( DC) .
Value shown refers to AC input reference voltage, VREF( AC ).
Table 1–15. Cyclone III Devices Single-Ended SSTL and HSTL I/O Standards Signal Specifications
I/O
Standard
VIL(DC) (V)
VIH(DC ) (V)
VIL(AC ) (V)
VIH (A C) (V)
VOL (V)
VOH (V)
IOL
(mA)
IOH
(mA)
Min
Max
Min
Max
Min
Max
Min
Max
Max
Min
SSTL-2
Class I
—
VREF –
0.18
VREF +
0.18
—
—
VREF –
0.35
VREF +
0.35
—
VTT –
0.57
VTT +
0.57
8.1
–8.1
SSTL-2
Class II
—
VREF –
0.18
VREF +
0.18
—
—
VREF –
0.35
VREF +
0.35
—
VTT –
0.76
VTT + 0.76
16.4
–16.4
SSTL-18
Class I
—
VREF –
0.125
VREF +
0.125
—
—
VREF –
0.25
VREF +
0.25
—
VTT –
0.475
VTT +
0.475
6.7
–6.7
SSTL-18
Class II
—
VREF –
0.125
VREF +
0.125
—
—
VREF –
0.25
VREF +
0.25
—
0.28
VC CIO –
0.28
13.4
–13.4
HSTL-18
Class I
—
VREF –
0.1
VREF +
0.1
—
—
VREF –
0.2
VREF +
0.2
—
0.4
VCC IO – 0.4
8
–8
HSTL-18
Class II
—
VREF –
0.1
VREF +
0.1
—
—
VREF –
0.2
VREF +
0.2
—
0.4
VC CIO –
0.4
16
–16
HSTL-15
Class I
—
VREF –
0.1
VREF +
0.1
—
—
VREF –
0.2
VREF +
0.2
—
0.4
VC CIO –
0.4
8
–8
HSTL-15
Class II
—
VREF –
0.1
VREF +
0.1
—
—
VREF –
0.2
VREF +
0.2
—
0.4
VC CIO –
0.4
16
–16
HSTL-12
Class I
–0.15
VREF –
0.08
VREF +
0.08
VCC IO + 0.15
–0.24
VREF –
0.15
VREF +
0.15
VC CIO + 0.24
0.25 ×
VCC IO
0.75 ×
VC CIO
8
–8
HSTL-12
Class II
–0.15
VREF –
0.08
VREF +
0.08
VCC IO + 0.15
–0.24
VREF –
0.15
VREF +
0.15
VC CIO + 0.24
0.25 ×
VCC IO
0.75 ×
VC CIO
14
–14
f
For more illustrations of receiver input and transmitter output waveforms, and for
other differential I/O standards, refer to the High-Speed Differential Interfaces in
Cyclone III Devices chapter.
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
1–13
Table 1–16. Cyclone III Devices Differential SSTL I/O Standard Specifications
VC CIO (V)
VSwing(D C) (V)
VX (A C) (V)
VSw ing(AC ) (V)
VOX (AC) (V)
I/O Standard
Min
Typ
Max
Min
Max
Min
Typ
Max
SSTL-2
Class I, II
2.375
2.5
2.625 0.36
VCC IO
VCC IO /2 – 0.2
—
VC CIO/2 +
0.2
0.7
SSTL-18
Class I, II
1.7
1.8
1.90
VCC IO
VCC IO/2 –
0.175
—
VC CIO/2 +
0.175
0.5
0.25
Min Max
Min
Typ
Max
VCC IO
VC CIO/2 –
0.125
—
VCC IO /2 +
0.125
VCC IO
VC CIO/2 –
0.125
—
VCC IO /2 +
0.125
Table 1–17. Cyclone III Devices Differential HSTL I/O Standard Specifications
VCC IO (V)
VDIF(DC) (V)
VX(A C) (V)
VCM (D C) (V)
VD IF(A C) (V)
I/O Standard
Min
Typ
Max
Min
Max
Min
Typ
Max
Min
Typ
Max
Mi
n
Max
HSTL-18
Class I, II
1.71
1.8
1.89
0.2
—
0.85
—
0.95
0.85
—
0.95
0.4
—
HSTL-15
Class I, II
1.425
1.5
1.575
0.2
—
0.71
—
0.79
0.71
—
0.79
0.4
—
HSTL-12
Class I, II
1.14
1.2
1.26
0.16
VC CIO
0.48 * VCC IO
—
0.52 *
VCC IO
0.48 *
VC CIO
—
0.52 *
VCCIO
0.3
0.48 *
VCCIO
Table 1–18. Cyclone III Devices Differential I/O Standard Specifications (Note 1)
I/O
Standard
LVPECL
(Row I/Os)
(4)
LVPECL
(Column
I/Os) (4)
LVDS (Row
I/Os)
LVDS
(Column
I/Os)
VC CIO (V)
Min
2.375
2.375
2.375
2.375
VID (mV)
Typ
2.5
2.5
2.5
2.5
Max
Min
2.625 100
2.625 100
2.625 100
2.625 100
Max
—
—
—
—
(Part 1 of 2)
VIcM (V) (2)
Min
Condition
VO D (mV) (3)
Max Min Typ
0.05
DM AX ≤ 500 Mbps
1.80
0.55
500 Mbps ≤ DM AX ≤
700 Mbps
1.80
1.05
DM AX > 700 Mbps
1.55
0.05
DM AX ≤ 500 Mbps
1.80
0.55
500 Mbps ≤DM AX ≤
700 Mbps
1.80
1.05
DM AX > 700 Mbps
1.55
0.05
VO S (V) (3)
Max
Min
Typ
Max
—
—
—
—
—
—
—
—
—
—
—
—
DM AX ≤ 500 Mbps
1.80
0.55
500 Mbps ≤DM AX ≤
700 Mbps
1.80 247
—
600
1.125 1.25 1.375
1.05
DM AX > 700 Mbps
1.55
0.05
DM AX ≤ 500 Mbps
1.80
0.55
500 Mbps ≤DM AX ≤
700 Mbps
1.80 247
—
600
1.125 1.25 1.375
1.05
DM AX > 700 Mbps
1.55
BLVDS
(Row I/Os)
(5)
2.375
2.5
2.625 100
—
—
—
—
—
—
—
—
—
—
BLVDS
(Column
I/Os) (5)
2.375
2.5
2.625 100
—
—
—
—
—
—
—
—
—
—
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–14
Chapter 1: Cyclone III Device Data Sheet
Electrical Characteristics
Table 1–18. Cyclone III Devices Differential I/O Standard Specifications (Note 1)
I/O
Standard
VC CIO (V)
VID (mV)
(Part 2 of 2)
VIcM (V) (2)
VO D (mV) (3)
Min
Typ
Max
Min
Max
Min
Condition
Max Min Typ
mini-LVDS
(Row I/Os)
(6)
2.375
2.5
2.625
—
—
—
—
—
300
mini-LVDS
(Column
I/Os) (6)
2.375
2.5
2.625
—
—
—
—
—
300
RSDS®
(Row
I/Os)(6)
2.375
2.5
2.625
—
—
—
—
RSDS
(Column
I/Os) (6)
2.375
2.5
2.625
—
—
—
PPDS®
(Row I/Os)
(6)
2.375
2.5
2.625
—
—
PPDS
(Column
I/Os) (6)
2.375
2.5
2.625
—
—
VO S (V) (3)
Max
Min
Typ
Max
—
600
1.0
1.2
1.4
—
600
1.0
1.2
1.4
—
100 200
600
0.5
1.2
1.5
—
—
100 200
600
0.5
1.2
1.5
—
—
—
100 200
600
0.5
1.2
1.4
—
—
—
100 200
600
0.5
1.2
1.4
Notes to Table 1–18:
(1)
(2)
(3)
(4)
(5)
(6)
For an explanation of terms used in Table 1–18, refer to “Transmitter Output Waveform” in “Glossary” on page 1–27.
VIN range: 0 V ≤VIN ≤1.85 V.
RL range: 90 ≤ RL ≤ 110 Ω.
LVPECL input standard is only supported at clock input. Output standard is not supported.
No fixed VIN , VOD , and VOS specifications for BLVDS. They are dependent on the system topology.
Mini-LVDS, RSDS, and PPDS standards are only supported at the output pins for Cyclone III devices.
Power Consumption
You can use the following methods to estimate power for a design:
■
the Excel-based EPE.
■
the Quartus II PowerPlay power analyzer feature.
The interactive Excel-based EPE is used prior to designing the device to get a
magnitude estimate of the device power. The Quartus II PowerPlay power analyzer
provides better quality estimates based on the specifics of the design after place-androute is complete. The PowerPlay power analyzer can apply a combination of userentered, simulation-derived, and estimated signal activities which, combined with
detailed circuit models, can yield very accurate power estimates.
f
For more information about power estimation tools, refer to the Early Power Estimator
User Guide and the PowerPlay Power Analysis chapter in volume 3 of the Quartus II
Handbook.
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
1–15
Switching Characteristics
This section provides the performance characteristics of the core and periphery blocks
for Cyclone III devices. All data is final and is based on actual silicon characterization
and testing. These numbers reflect the actual performance of the device under
worst-case silicon process, voltage, and junction temperature conditions.
Core Performance Specifications
Clock Tree Specifications
Table 1–19 lists the clock tree specifications for Cyclone III devices.
Table 1–19. Cyclone III Devices Clock Tree Performance
Performance
Device
Unit
C6
C7
C8
EP3C5
500
437.5
402
MHz
EP3C10
500
437.5
402
MHz
EP3C16
500
437.5
402
MHz
EP3C25
500
437.5
402
MHz
EP3C40
500
437.5
402
MHz
EP3C55
500
437.5
402
MHz
EP3C80
500
437.5
402
MHz
EP3C120
(1)
437.5
402
MHz
Note to Table 1–19:
(1) EP3C120 offered in C7, C8, and I7 grades only.
PLL Specifications
Table 1–20 describes the PLL specifications for Cyclone III devices when operating in
the commercial junction temperature range (0°C to 85°C), the industrial junction
temperature range (–40°C to 100°C), and the automotive junction temperature range
(–40°Cto 125°C). For more information about PLL block, refer to “PLL Block” in
“Glossary” on page 1–27.
Table 1–20. Cyclone III Devices PLL Specifications (Note 1)
Symbol
(Part 1 of 2)
Parameter
Min
Typ
Max
Unit
fIN (2)
Input clock frequency
5
—
472.5
MHz
fINPF D
PFD input frequency
5
—
325
MHz
fVC O (3)
PLL internal VCO operating range
600
—
1300
MHz
fINDUTY
Input clock duty cycle
40
—
60
%
tINJITTER_C CJ (4)
Input clock cycle-to-cycle jitter
FREF ≥ 100 MHz
—
—
0.15
UI
FREF < 100 MHz
—
—
±750
ps
PLL output frequency
—
—
472.5
MHz
fOUT_EXT (external clock output)
(2)
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–16
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
Table 1–20. Cyclone III Devices PLL Specifications (Note 1)
Symbol
(Part 2 of 2)
Min
Typ
Max
Unit
PLL output frequency (–6 speed grade)
—
—
472.5
MHz
PLL output frequency (–7 speed grade)
—
—
450
MHz
PLL output frequency (–8 speed grade)
—
—
402.5
MHz
tOUTDUTY
Duty cycle for external clock output (when set to 50%)
45
50
55
%
tLOCK
Time required to lock from end of device configuration
—
—
1
ms
tDLOCK
Time required to lock dynamically (after switchover,
reconfiguring any non-post-scale counters/delays or
areset is deasserted)
—
—
1
ms
Dedicated clock output period jitter
FOUT ≥ 100 MHz
—
—
300
ps
FOUT < 100 MHz
—
—
30
mUI
Dedicated clock output cycle-to-cycle jitter
FOUT ≥ 100 MHz
—
—
300
ps
FOUT < 100 MHz
—
—
30
mUI
Regular I/O period jitter
FOUT ≥ 100 MHz
—
—
650
ps
FOUT < 100 MHz
—
—
75
mUI
Regular I/O cycle-to-cycle jitter
FOUT ≥ 100 MHz
—
—
650
ps
fOUT (to global clock)
tOUTJITTER_PERIOD_DEDC LK (5)
tOUTJITTER_CCJ _DEDCLK (5)
tOUTJITTER_PERIOD_IO (5)
tOUTJITTER_CCJ _IO (5)
Parameter
FOUT < 100 MHz
—
—
75
mUI
tPLL_PSERR
Accuracy of PLL phase shift
—
—
±50
ps
tARESET
Minimum pulse width on areset signal.
10
—
—
ns
tCONF IGPLL
Time required to reconfigure scan chains for PLLs
—
3.5 (6)
—
SCANCLK
cycles
fSC ANC LK
scanclk frequency
—
—
100
MHz
Notes to Table 1–20:
(1) VCC D_P LL should always be connected to VC CINT through decoupling capacitor and ferrite bead.
(2) This parameter is limited in the Quartus II software by the I/O maximum frequency. The maximum I/O frequency is different for each I/O standard.
(3) The VCO frequency reported by the Quartus II software in the PLL summary section of the compilation report takes into consideration the VC O post-scale
counter K value. Therefore, if the counter K has a value of 2, the frequency reported can be lower than the fV CO specification.
(4) A high input jitter directly affects the PLL output jitter. To have low PLL output clock jitter, you must provide a clean clock source, which is less than 200 ps.
(5) Peak-to-peak jitter with a probability level of 10–12 (14 sigma, 99.99999999974404% confidence level). The output jitter specification applies to the intrinsic
jitter of the PLL, when an input jitter of 30 ps is applied.
(6) With 100 MHz scanclk frequency.
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
1–17
Embedded Multiplier Specifications
Table 1–21 describes the embedded multiplier specifications for Cyclone III devices.
Table 1–21. Cyclone III Devices Embedded Multiplier Specifications
Resources Used
Performance
Mode
Unit
Number of Multipliers
C6
C7, I7, A7
C8
9 × 9-bit
multiplier
1
340
300
260
MHz
18 × 18-bit
multiplier
1
287
250
200
MHz
Memory Block Specifications
Table 1–22 describes the M9K memory block specifications for Cyclone III devices.
Table 1–22. Cyclone III Devices Memory Block Performance Specifications
Resources Used
Memory
M9K Block
Mode
Performance
LEs
M9K
Memory
C6
C7, I7, A7
C8
Unit
FIFO 256 × 36
47
1
315
274
238
MHz
Single-port 256 × 36
0
1
315
274
238
MHz
Simple dual-port 256 × 36 CLK
0
1
315
274
238
MHz
True dual port 512 × 18 single CLK
0
1
315
274
238
MHz
Configuration and JTAG Specifications
Table 1–23 lists the configuration mode specifications for Cyclone III devices.
Table 1–23. Cyclone III Devices Configuration Mode Specifications
Programming Mode
DCLK Fm ax
Unit
Passive Serial (PS)
133
MHz
Fast Passive Parallel (FPP) (1)
100
MHz
Note to Table 1–23:
(1) EP3C40 and smaller density members support 133 MHz.
Table 1–24 lists the active configuration mode specifications for Cyclone III devices.
Table 1–24. Cyclone III Devices Active Configuration Mode Specifications
Programming Mode
© January 2010
DCLK Range
Unit
Active Parallel (AP)
20 – 40
MHz
Active Serial (AS)
20 – 40
MHz
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–18
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
Table 1–25 lists the JTAG timing parameters and values for Cyclone III devices.
Table 1–25. Cyclone III Devices JTAG Timing Parameters
Symbol
(Note 1)
Parameter
Min
Max
Unit
tJC P
TCK clock period
40
—
ns
tJC H
TCK clock high time
20
—
ns
tJC L
TCK clock low time
20
—
ns
tJP SU_TDI
JTAG port setup time for TDI (2)
1
—
ns
tJP SU_TM S
JTAG port setup time for TMS (2)
3
—
ns
tJP H
JTAG port hold time
10
—
ns
tJP CO
JTAG port clock to output (2)
—
15
ns
tJP ZX
JTAG port high impedance to valid output (2)
—
15
ns
tJP XZ
JTAG port valid output to high impedance (2)
—
15
ns
tJS SU
Capture register setup time (2)
5
—
ns
tJS H
Capture register hold time
10
—
ns
tJS CO
Update register clock to output
—
25
ns
tJS ZX
Update register high impedance to valid output
—
25
ns
tJS XZ
Update register valid output to high impedance
—
25
ns
Notes to Table 1–25:
(1) For more information about JTAG waveforms, refer to “JTAG Waveform” in “Glossary” on page 1–27.
(2) The specification is shown for 3.3-, 3.0-, and 2.5-V LVTTL/LVCMOS operation of JTAG pins. For 1.8-V LVTTL/LVCMOS
and 1.5-V LVCMOS, the JTAG port clock to output time is 16 ns.
Periphery Performance
High-Speed I/O Specifications
Table 1–26 through Table 1–31 list the high-speed I/O timing for Cyclone III devices.
For definitions of high-speed timing specifications, refer to “Glossary” on page 1–27.
Table 1–26. Cyclone III Devices RSDS Transmitter Timing Specifications
(Note 1), (2) (Part 1 of 2)
C6
Symbol
C7, I7
C8, A7
Modes
fHSC LK
(input clock
frequency)
Cyclone III Device Handbook, Volume 2
Unit
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
×10
10
—
180
10
—
155.5
10
—
155.5
MHz
×8
10
—
180
10
—
155.5
10
—
155.5
MHz
×7
10
—
180
10
—
155.5
10
—
155.5
MHz
×4
10
—
180
10
—
155.5
10
—
155.5
MHz
×2
10
—
180
10
—
155.5
10
—
155.5
MHz
×1
10
—
360
10
—
311
10
—
311
MHz
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
1–19
Table 1–26. Cyclone III Devices RSDS Transmitter Timing Specifications
(Note 1), (2) (Part 2 of 2)
C6
Symbol
C7, I7
C8, A7
Modes
Unit
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
×10
100
—
360
100
—
311
100
—
311
Mbps
×8
80
—
360
80
—
311
80
—
311
Mbps
×7
70
—
360
70
—
311
70
—
311
Mbps
×4
40
—
360
40
—
311
40
—
311
Mbps
×2
20
—
360
20
—
311
20
—
311
Mbps
×1
10
—
360
10
—
311
10
—
311
Mbps
tDUTY
—
45
—
55
45
—
55
45
—
55
%
TCCS
—
—
—
200
—
—
200
—
—
200
ps
Output jitter
(peak to peak)
—
—
—
500
—
—
500
—
—
550
ps
tRISE
20 – 80%, CLOA D = 5 pF
—
500
—
—
500
—
—
500
—
ps
tFALL
20 – 80%, CLOA D = 5 pF
—
500
—
—
500
—
—
500
—
ps
—
—
—
1
—
—
1
—
—
1
ms
Device operation in
Mbps
tLOCK (3)
Notes to Table 1–26:
(1) Applicable for true RSDS and emulated RSDS_E_3R transmitter.
(2) True RSDS transmitter is only supported at output pin of Row I/O (Banks 1, 2, 5, and 6). Emulated RSDS transmitter is supported at the output
pin of all I/O banks.
(3) tLOC K is the time required for the PLL to lock from the end of device configuration.
Table 1–27. Cyclone III Devices Emulated RSDS_E_1R Transmitter Timing Specifications (Note 1) (Part 1 of 2)
C6
Symbol
C7, I7
C8, A7
Modes
Unit
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
×10
10
—
85
10
—
85
10
—
85
MHz
×8
10
—
85
10
—
85
10
—
85
MHz
×7
10
—
85
10
—
85
10
—
85
MHz
×4
10
—
85
10
—
85
10
—
85
MHz
×2
10
—
85
10
—
85
10
—
85
MHz
×1
10
—
170
10
—
170
10
—
170
MHz
×10
100
—
170
100
—
170
100
—
170
Mbps
×8
80
—
170
80
—
170
80
—
170
Mbps
×7
70
—
170
70
—
170
70
—
170
Mbps
×4
40
—
170
40
—
170
40
—
170
Mbps
×2
20
—
170
20
—
170
20
—
170
Mbps
×1
10
—
170
10
—
170
10
—
170
Mbps
tDUTY
—
45
—
55
45
—
55
45
—
55
%
TCCS
—
—
—
200
—
—
200
—
—
200
ps
Output jitter
(peak to
peak)
—
—
—
500
—
—
500
—
—
550
ps
fHSC LK (input
clock
frequency)
Device
operation in
Mbps
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–20
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
Table 1–27. Cyclone III Devices Emulated RSDS_E_1R Transmitter Timing Specifications (Note 1) (Part 2 of 2)
C6
Symbol
tRISE
tFALL
C7, I7
C8, A7
Modes
20 – 80%,
CLOAD = 5 pF
20 – 80%,
CLOAD = 5 pF
tLOCK (2)
—
Unit
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
—
500
—
—
500
—
—
500
—
ps
—
500
—
—
500
—
—
500
—
ps
—
—
1
—
—
1
—
—
1
ms
Notes to Table 1–27:
(1) Emulated RSDS_E_1R transmitter is supported at the output pin of all I/O banks.
(2) tLOC K is the time required for the PLL to lock from the end of device configuration.
Table 1–28. Cyclone III Devices Mini-LVDS Transmitter Timing Specifications (Note 1), (2)
C6
Symbol
C7, I7
C8, A7
Modes
Unit
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
×10
10
—
200
10
—
155.5
10
—
155.5
MHz
×8
10
—
200
10
—
155.5
10
—
155.5
MHz
×7
10
—
200
10
—
155.5
10
—
155.5
MHz
×4
10
—
200
10
—
155.5
10
—
155.5
MHz
×2
10
—
200
10
—
155.5
10
—
155.5
MHz
×1
10
—
400
10
—
311
10
—
311
MHz
×10
100
—
400
100
—
311
100
—
311
Mbps
×8
80
—
400
80
—
311
80
—
311
Mbps
×7
70
—
400
70
—
311
70
—
311
Mbps
×4
40
—
400
40
—
311
40
—
311
Mbps
×2
20
—
400
20
—
311
20
—
311
Mbps
×1
10
—
400
10
—
311
10
—
311
Mbps
tDUTY
—
45
—
55
45
—
55
45
—
55
%
TCCS
—
—
—
200
—
—
200
—
—
200
ps
Output jitter
(peak to
peak)
—
—
—
500
—
—
500
—
—
550
ps
—
500
—
—
500
—
—
500
—
ps
—
500
—
—
500
—
—
500
—
ps
—
—
1
—
—
1
—
—
1
ms
fHSC LK (input
clock
frequency)
Device
operation in
Mbps
tRISE
tFALL
20 – 80%,
CLOAD = 5 pF
20 – 80%,
CLOAD = 5 pF
tLOCK (3)
—
Notes to Table 1–28:
(1) Applicable for true and emulated mini-LVDS transmitter.
(2) True mini-LVDS transmitter is only supported at the output pin of Row I/O (Banks 1, 2, 5, and 6). Emulated mini-LVDS transmitter is supported
at the output pin of all I/O banks.
(3) tLOC K is the time required for the PLL to lock from the end of device configuration.
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
1–21
Table 1–29. Cyclone III Devices True LVDS Transmitter Timing Specifications (Note 1)
C6
Symbol
C7, I7
C8, A7
Modes
Unit
Min
Max
Min
Max
Min
Max
×10
10
420
10
370
10
320
MHz
×8
10
420
10
370
10
320
MHz
×7
10
420
10
370
10
320
MHz
×4
10
420
10
370
10
320
MHz
×2
10
420
10
370
10
320
MHz
×1
10
420
10
402.5
10
402.5
MHz
×10
100
840
100
740
100
640
Mbps
×8
80
840
80
740
80
640
Mbps
×7
70
840
70
740
70
640
Mbps
×4
40
840
40
740
40
640
Mbps
×2
20
840
20
740
20
640
Mbps
×1
10
420
10
402.5
10
402.5
Mbps
tDUTY
—
45
55
45
55
45
55
%
TCCS
—
—
200
—
200
—
200
ps
Output jitter
(peak to peak)
—
—
500
—
500
—
550
ps
tLOCK (2)
—
—
1
—
1
—
1
ms
fHSC LK (input
clock frequency)
HSIODR
Notes to Table 1–29:
(1) True LVDS transmitter is only supported at the output pin of Row I/O (Banks 1, 2, 5, and 6).
(2) tLOC K is the time required for the PLL to lock from the end of device configuration.
Table 1–30. Cyclone III Devices Emulated LVDS Transmitter Timing Specifications (Note 1) (Part 1
of 2)
C6
Symbol
fHSC LK (input clock
frequency)
HSIODR
tDUTY
© January 2010
Altera Corporation
C7, I7
C8, A7
Modes
Unit
Min
Max
Min
Max
Min
Max
×10
10
320
10
320
10
275
MHz
×8
10
320
10
320
10
275
MHz
×7
10
320
10
320
10
275
MHz
×4
10
320
10
320
10
275
MHz
×2
10
320
10
320
10
275
MHz
×1
10
402.5
10
402.5
10
402.5
MHz
×10
100
640
100
640
100
550
Mbps
×8
80
640
80
640
80
550
Mbps
×7
70
640
70
640
70
550
Mbps
×4
40
640
40
640
40
550
Mbps
×2
20
640
20
640
20
550
Mbps
×1
10
402.5
10
402.5
10
402.5
Mbps
—
45
55
45
55
45
55
%
Cyclone III Device Handbook, Volume 2
1–22
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
Table 1–30. Cyclone III Devices Emulated LVDS Transmitter Timing Specifications (Note 1) (Part 2
of 2)
C6
Symbol
C7, I7
C8, A7
Modes
Unit
Min
Max
Min
Max
Min
Max
TCCS
—
—
200
—
200
—
200
ps
Output jitter
(peak to peak)
—
—
500
—
500
—
550
ps
tLOCK (2)
—
—
1
—
1
—
1
ms
Notes to Table 1–30:
(1) Emulated LVDS transmitter is supported at the output pin of all I/O banks.
(2) tLOC K is the time required for the PLL to lock from the end of device configuration.
Table 1–31. Cyclone III Devices LVDS Receiver Timing Specifications (Note 1)
C6
Symbol
fHSC LK (input clock
frequency)
C7, I7
C8, A7
Modes
Unit
Min
Max
Min
Max
Min
Max
×10
10
437.5
10
370
10
320
MHz
×8
10
437.5
10
370
10
320
MHz
×7
10
437.5
10
370
10
320
MHz
×4
10
437.5
10
370
10
320
MHz
×2
10
437.5
10
370
10
320
MHz
×1
10
437.5
10
402.5
10
402.5
MHz
×10
100
875
100
740
100
640
Mbps
×8
80
875
80
740
80
640
Mbps
×7
70
875
70
740
70
640
Mbps
×4
40
875
40
740
40
640
Mbps
×2
20
875
20
740
20
640
Mbps
×1
10
437.5
10
402.5
10
402.5
Mbps
SW
—
—
400
—
400
—
400
ps
Input jitter
tolerance
—
—
500
—
500
—
550
ps
tLOCK (2)
—
—
1
—
1
—
1
ms
HSIODR
Notes to Table 1–31:
(1) LVDS receiver is supported at all banks.
(2) tLOC K is the time required for the PLL to lock from the end of device configuration.
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
1–23
External Memory Interface Specifications
Cyclone III devices support external memory interfaces up to 200 MHz. The external
memory interfaces for Cyclone III devices are auto-calibrating and easy to implement.
f
For more information about external memory system performance specifications,
board design guidelines, timing analysis, simulation, and debugging information,
refer to Literature: External Memory Interfaces.
Table 1–32 lists the FPGA sampling window specifications for Cyclone III devices.
Table 1–32. Cyclone III Devices FPGA Sampling Window (SW) Requirement – Read Side (Note 1)
Column I/Os
Row I/Os
Wraparound Mode
Memory Standard
Setup
Hold
Setup
Hold
Setup
Hold
C6
DDR2 SDRAM
580
550
690
640
850
800
DDR SDRAM
585
535
700
650
870
820
QDRII SRAM
785
735
805
755
905
855
985
930
C7
DDR2 SDRAM
705
650
770
715
DDR SDRAM
675
620
795
740
970
915
QDRII SRAM
900
845
910
855
1085
1030
C8
DDR2 SDRAM
785
720
930
870
1115
1055
DDR SDRAM
800
740
915
855
1185
1125
QDRII SRAM
1050
990
1065
1005
1210
1150
855
800
1040
985
I7
DDR2 SDRAM
765
710
DDR SDRAM
745
690
880
825
1000
945
QDRII SRAM
945
890
955
900
1130
1075
A7
DDR2 SDRAM
805
745
1020
960
1145
1085
DDR SDRAM
880
820
955
935
1220
1160
QDRII SRAM
1090
1030
1105
1045
1250
1190
Note to Table 1–32:
(1) Column I/Os refer to top and bottom I/Os. Row I/Os refer to right and left I/Os. Wraparound mode refers to the combination of column and row
I/Os.
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–24
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
Table 1–33 lists the transmitter channel-to-channel skew specifications for Cyclone III
devices.
Table 1–33. Cyclone III Devices Transmitter Channel-to-Channel Skew (TCCS) – Write Side (Note 1)
Memory
Standard
Column I/Os (ps)
Row I/Os (ps)
(Part 1 of 2)
Wraparound Mode (ps)
I/O Standard
Lead
Lag
Lead
Lag
Lead
Lag
C6
DDR2 SDRAM
DDR SDRAM
QDRII SRAM
SSTL-18 Class I
790
380
790
380
890
480
SSTL-18 Class II
870
490
870
490
970
590
SSTL-2 Class I
750
320
750
320
850
420
SSTL-2 Class II
860
350
860
350
960
450
1.8 V HSTL Class I
780
410
780
410
880
510
1.8 V HSTL Class II
830
510
830
510
930
610
C7
DDR2 SDRAM
DDR SDRAM
QDRII SRAM
SSTL-18 Class I
915
410
915
410
1015
510
SSTL-18 Class II
1025
545
1025
545
1125
645
SSTL-2 Class I
880
340
880
340
980
440
SSTL-2 Class II
1010
380
1010
380
1110
480
1.8 V HSTL Class I
910
450
910
450
1010
550
1.8 V HSTL Class II
1010
570
1010
570
1110
670
C8
DDR2 SDRAM
DDR SDRAM
QDRII SRAM
SSTL-18 Class I
1040
440
1040
440
1140
540
SSTL-18 Class II
1180
600
1180
600
1280
700
SSTL-2 Class I
1010
360
1010
360
1110
460
SSTL-2 Class II
1160
410
1160
410
1260
510
1.8 V HSTL Class I
1040
490
1040
490
1140
590
1.8 V HSTL Class II
1190
630
1190
630
1290
730
I7
DDR2 SDRAM
DDR SDRAM
QDRII SRAM
SSTL-18 Class I
961
431
961
431
1061
531
SSTL-18 Class II
1076
572
1076
572
1176
672
SSTL-2 Class I
924
357
924
357
1024
457
SSTL-2 Class II
1061
399
1061
399
1161
499
1.8 V HSTL Class I
956
473
956
473
1056
573
1.8 V HSTL Class II
1061
599
1061
599
1161
699
SSTL-18 Class I
1092
462
1092
462
1192
562
SSTL-18 Class II
1239
630
1239
630
1339
730
SSTL-2 Class I
1061
378
1061
378
1161
478
SSTL-2 Class II
1218
431
1218
431
1318
531
A7
DDR2 SDRAM
(2)
DDR SDRAM
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
1–25
Table 1–33. Cyclone III Devices Transmitter Channel-to-Channel Skew (TCCS) – Write Side (Note 1)
Column I/Os (ps)
Memory
Standard
Row I/Os (ps)
(Part 2 of 2)
Wraparound Mode (ps)
I/O Standard
QDRII SRAM
Lead
Lag
Lead
Lag
Lead
Lag
1.8 V HSTL Class I
1092
515
1092
515
1192
615
1.8 V HSTL Class II
1250
662
1250
662
1350
762
Notes to Table 1–33:
(1) Column I/O banks refer to top and bottom I/Os. Row I/O banks refer to right and left I/Os. Wraparound mode refers to the combination of column
and row I/Os.
(2) For DDR2 SDRAM write timing performance on Columns I/O for C8 and A7 devices, 97.5 degree phase offset is required.
Table 1–34 lists the memory output clock jitter specifications for Cyclone III devices.
Table 1–34. Cyclone III Devices Memory Output Clock Jitter Specifications (Note 1), (2)
Parameter
Symbol
Min
Max
Unit
Clock period jitter
tJIT(per)
-125
125
ps
Cycle-to-cycle period jitter
tJIT(cc)
-200
200
ps
Duty cycle jitter
t JIT(duty)
-150
150
ps
Notes to Table 1–34:
(1) The memory output clock jitter measurements are for 200 consecutive clock cycles, as specified in the JEDEC DDR2 standard.
(2) The clock jitter specification applies to memory output clock pins generated using DDIO circuits clocked by a PLL output routed on a global
clock network.
Duty Cycle Distortion Specifications
Table 1–35 lists the worst case duty cycle distortion for Cyclone III devices.
Table 1–35. Duty Cycle Distortion on Cyclone III Devices I/O Pins
C6
(Note 1), (2)
C7, I7
C8, A7
Symbol
Output Duty Cycle
Unit
Min
Max
Min
Max
Min
Max
45
55
45
55
45
55
%
Notes to Table 1–35:
(1) Duty cycle distortion specification applies to clock outputs from PLLs, global clock tree, and IOE driving dedicated
and general purpose I/O pins.
(2) Cyclone III devices meet specified duty cycle distortion at maximum output toggle rate for each combination of
I/O standard and current strength.
OCT Calibration Timing Specification
Table 1–36 lists the duration of calibration for series OCT with calibration at device
power-up for Cyclone III devices.
Table 1–36. Cyclone III Devices Timing Specification for Series OCT with Calibration at Device
Power-Up (Note 1)
Symbol
tOCTC AL
Description
Duration of series OCT with
calibration at device power-up
Maximum
Unit
20
µs
Notes to Table 1–36:
(1) OCT calibration takes place after device configuration, before entering user mode.
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–26
Chapter 1: Cyclone III Device Data Sheet
Switching Characteristics
IOE Programmable Delay
Table 1–37 and Table 1–38 list IOE programmable delay for Cyclone III devices.
Table 1–37. Cyclone III Devices IOE Programmable Delay on Column Pins (Note 1), (2)
Max Offset
Parameter
Paths
Affected
Number
of
Settings
Min
Offset
Fast Corner
Slow Corner
Unit
A7, I7
C6
C6
C7
C8
I7
A7
Input delay from pin to
internal cells
Pad to I/O
dataout to
core
7
0
1.211
1.314
2.175
2.32
2.386
2.366
2.49
ns
Input delay from pin to
input register
Pad to I/O
input register
8
0
1.203
1.307
2.19
2.387
2.54
2.43
2.545
ns
Delay from output
register to output pin
I/O output
register to
pad
2
0
0.479
0.504
0.915
1.011
1.107
1.018
1.048
ns
Input delay from
dual-purpose clock pin
to fan-out destinations
Pad to global
clock
network
12
0
0.664
0.694
1.199
1.378
1.532
1.392
1.441
ns
Notes to Table 1–37:
(1) The incremental values for the settings are generally linear. For exact values of each setting, use the latest version of the Quartus II software.
(2) The minimum and maximum offset timing numbers are in reference to setting ‘0’ as available in the Quartus II software.
Table 1–38. Cyclone III Devices IOE Programmable Delay on Row Pins
(Note 1), (2)
Max Offset
Parameter
Paths
Affected
Number
of
Settings
Min
Offset
Fast Corner
Slow Corner
Unit
A7, I7
C6
C6
C7
C8
I7
A7
Input delay from pin to
internal cells
Pad to I/O
dataout to
core
7
0
1.209
1.314
2.174
2.335
2.406
2.381
2.505
ns
Input delay from pin to
input register
Pad to I/O
input register
8
0
1.207
1.312
2.202
2.402
2.558
2.447
2.557
ns
Delay from output
register to output pin
I/O output
register to
pad
2
0
0.51
0.537
0.962
1.072
1.167
1.074
1.101
ns
12
0
0.669
0.698
1.207
1.388
1.542
1.403
1.45
ns
Input delay from
Pad to global
dual-purpose clock pin
clock network
to fan-out destinations
Notes to Table 1–38:
(1) The incremental values for the settings are generally linear. For exact values of each setting, use the latest version of Quartus II software.
(2) The minimum and maximum offset timing numbers are in reference to setting ‘0’ as available in the Quartus II software
Cyclone III Device Handbook, Volume 2
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
I/O Timing
1–27
I/O Timing
You can use the following methods to determine the I/O timing:
■
the Excel-based I/O Timing.
■
the Quartus II timing analyzer.
The Excel-based I/O Timing provides pin timing performance for each device density
and speed grade. The data is typically used prior to designing the FPGA to get a
timing budget estimation as part of the link timing analysis. The Quartus II timing
analyzer provides a more accurate and precise I/O timing data based on the specifics
of the design after place-and-route is complete.
f
The Excel-based I/O Timing spreadsheet is downloadable from Cyclone III Devices
Literature website.
Glossary
Table 1–39 lists the glossary for this chapter.
Table 1–39. Glossary (Part 1 of 5)
Letter
Term
Definitions
A
—
—
B
—
—
C
—
—
D
—
—
E
—
—
fHS CLK
HIGH-SPEED I/O Block: High-speed receiver/transmitter input and output clock frequency.
GCLK
Input pin directly to Global Clock network.
GCLK PLL
Input pin to Global Clock network through PLL.
H
HSIODR
HIGH-SPEED I/O Block: Maximum/minimum LVDS data transfer rate (HSIODR = 1/TUI).
I
Input Waveforms
for the SSTL
Differential I/O
Standard
F
G
VIH
VSWING
VREF
VIL
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–28
Chapter 1: Cyclone III Device Data Sheet
Glossary
Table 1–39. Glossary (Part 2 of 5)
Letter
Term
Definitions
TMS
TDI
t JCP
t JCH
t JPSU_TDI
t JPSU_TMS
t JCL
t JPH
TCK
J
JTAG Waveform
tJPZX
t JPXZ
t JPCO
TDO
tJSSU
Signal
to be
Captured
t JSH
tJSZX
t JSCO
t JSXZ
Signal
to be
Driven
K
—
—
L
—
—
M
—
—
N
—
—
O
—
—
The following block diagram highlights the PLL Specification parameters.
CLKOUT Pins
Switchover
fOUT _EXT
CLK
fIN
N
fINPFD
PFD
P
PLL Block
CP
LF
Core Clock
VCO fVCO
Counters
C0..C4
fOUT
GCLK
Phase tap
M
Key
Reconfigurable in User Mode
Q
—
Cyclone III Device Handbook, Volume 2
—
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Glossary
1–29
Table 1–39. Glossary (Part 3 of 5)
Letter
Term
RL
Definitions
Receiver differential input discrete resistor (external to Cyclone III devices).
Receiver Input Waveform for LVDS and LVPECL Differential Standards.
Single-Ended Waveform
Positive Channel (p) = VIH
VID
Negative Channel (n) = VIL
VCM
R
Ground
Receiver Input
Waveform
Differential Waveform (Mathematical Function of Positive & Negative Channel)
VID
0V
VID
p -n
RSKM (Receiver
input skew
margin)
HIGH-SPEED I/O Block: The total margin left after accounting for the sampling window and TCCS.
RSKM = (TUI – SW – TCCS) / 2.
VCCIO
VOH
VIH (AC )
VIH(DC)
VREF
S
VIL(DC)
VIL(AC )
Single-ended
Voltage
referenced I/O
Standard
VOL
VSS
The JEDEC standard for SSTl and HSTL I/O standards defines both the AC and DC input signal
values. The AC values indicate the voltage levels at which the receiver must meet its timing
specifications. The DC values indicate the voltage levels at which the final logic state of the
receiver is unambiguously defined. After the receiver input crosses the AC value, the receiver
changes to the new logic state. The new logic state is then maintained as long as the input stays
beyond the DC threshold. This approach is intended to provide predictable receiver timing in the
presence of input waveform ringing.
SW (Sampling
Window)
© January 2010
HIGH-SPEED I/O Block: The period of time during which the data must be valid to capture it
correctly. The setup and hold times determine the ideal strobe position in the sampling window.
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–30
Chapter 1: Cyclone III Device Data Sheet
Glossary
Table 1–39. Glossary (Part 4 of 5)
Letter
T
Term
Definitions
tC
High-speed receiver/transmitter input and output clock period.
TCCS (Channelto-channel-skew)
HIGH-SPEED I/O Block: The timing difference between the fastest and slowest output edges,
including t C O variation and clock skew. The clock is included in the TCCS measurement.
tcin
Delay from clock pad to I/O input register.
tC O
Delay from clock pad to I/O output.
tcout
Delay from clock pad to I/O output register.
tDUTY
HIGH-SPEED I/O Block: Duty cycle on high-speed transmitter output clock.
tFA LL
Signal High-to-low transition time (80–20%).
tH
Input register hold time.
Timing Unit
Interval (TUI)
HIGH-SPEED I/O block: The timing budget allowed for skew, propagation delays, and data
sampling window. (TUI = 1/(Receiver Input Clock Frequency Multiplication Factor) = tC /w).
tINJITTER
Period jitter on PLL clock input.
tOUTJITTER_DEDC LK
Period jitter on dedicated clock output driven by a PLL.
tOUTJITTER_IO
Period jitter on general purpose I/O driven by a PLL.
tpllcin
Delay from PLL inclk pad to I/O input register.
tpllcout
Delay from PLL inclk pad to I/O output register.
Transmitter Output Waveforms for the LVDS, mini-LVDS, PPDS and RSDS Differential I/O
Standards
Single-Ended Waveform
Positive Channel (p) = VOH
VOD
Negative Channel (n) = VOL
Vos
Transmitter
Output Waveform
Ground
Differential Waveform (Mathematical Function of Positive & Negative Channel)
VOD
0V
VOD
p -n
U
tRISE
Signal Low-to-high transition time (20–80%).
tS U
Input register setup time.
—
Cyclone III Device Handbook, Volume 2
—
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Glossary
1–31
Table 1–39. Glossary (Part 5 of 5)
Letter
V
Term
Definitions
VC M( DC)
DC Common Mode Input Voltage.
VDIF( AC )
AC differential Input Voltage: The minimum AC input differential voltage required for switching.
VDIF( DC)
DC differential Input Voltage: The minimum DC input differential voltage required for switching.
VIC M
Input Common Mode Voltage: The common mode of the differential signal at the receiver.
VID
Input differential Voltage Swing: The difference in voltage between the positive and
complementary conductors of a differential transmission at the receiver.
VIH
Voltage Input High: The minimum positive voltage applied to the input which is accepted by the
device as a logic high.
VIH(A C)
High-level AC input voltage.
VIH(DC )
High-level DC input voltage.
VIL
Voltage Input Low: The maximum positive voltage applied to the input which is accepted by the
device as a logic low.
VIL ( AC )
Low-level AC input voltage.
VIL ( DC)
Low-level DC input voltage.
VIN
DC input voltage.
VOC M
Output Common Mode Voltage: The common mode of the differential signal at the transmitter.
VOD
Output differential Voltage Swing: The difference in voltage between the positive and
complementary conductors of a differential transmission at the transmitter. VOD = VOH – VOL.
VOH
Voltage Output High: The maximum positive voltage from an output which the device considers is
accepted as the minimum positive high level.
VOL
Voltage Output Low: The maximum positive voltage from an output which the device considers is
accepted as the maximum positive low level.
VOS
Output offset voltage: VOS = (VOH + VOL) / 2.
VOX ( AC)
AC differential Output cross point voltage: The voltage at which the differential output signals must
cross.
VREF
Reference voltage for SSTL, HSTL I/O Standards.
VREF (A C)
AC input reference voltage for SSTL, HSTL I/O Standards. VREF (AC ) = VREF (DC) + noise. The
peak-to-peak AC noise on VREF should not exceed 2% of VREF (DC).
VREF (DC )
DC input reference voltage for SSTL, HSTL I/O Standards.
VS WING (A C)
AC differential Input Voltage: AC Input differential voltage required for switching. For the SSTL
Differential I/O Standard, refer to Input Waveforms.
VS WING (DC )
DC differential Input Voltage: DC Input differential voltage required for switching. For the SSTL
Differential I/O Standard, refer to Input Waveforms.
VTT
Termination voltage for SSTL, HSTL I/O Standards.
VX ( AC)
AC differential Input cross point Voltage: The voltage at which the differential input signals must
cross.
W
—
—
X
—
—
Y
—
—
Z
—
—
© January 2010
Altera Corporation
Cyclone III Device Handbook, Volume 2
1–32
Chapter 1: Cyclone III Device Data Sheet
Document Revision History
Document Revision History
Table 1–40 lists the revision history for this chapter.
Table 1–40. Document Revision History
Date
January 2010
(Part 1 of 3)
Version
3.3
Changes Made
■
Removed Table 1-32 and Table 1-33.
■
Added Literature: External Memory Interfaces reference.
December 2009
3.2
Minor changes to the text.
July 2009
3.1
Minor edit to the hyperlinks.
June 2009
October 2008
July 2008
3.0
2.2
2.1
Cyclone III Device Handbook, Volume 2
■
Changed chapter title from DC and Switching Characteristics to “Cyclone III
Device Data Sheet” on page 1–1.
■
Updated (Note 1) to Table 1–23 on page 1–17.
■
Updated “External Memory Interface Specifications” on page 1–23.
■
Replaced Table 1–32 on page 1–23.
■
Replaced Table 1–33 on page 1–23.
■
Added Table 1–36 on page 1–26.
■
Updated “I/O Timing” on page 1–28.
■
Removed “Typical Design Performance” section.
■
Removed “I/O Timing” subsections.
■
Updated chapter to new template.
■
Updated Table 1–1, Table 1–3, and Table 1–18.
■
Added (Note 7) to Table 1–3.
■
Added the “OCT Calibration Timing Specification” section.
■
Updated “Glossary” section.
■
Updated Table 1–38.
■
Added BLVDS information (I/O standard) into Table 1–39, Table 1–40,
Table 1–41, Table 1–42.
■
Updated Table 1–43, Table 1–46, Table 1–47, Table 1–48, Table 1–49,
Table 1–50, Table 1–51, Table 1–52, Table 1–53, Table 1–54, Table 1–55,
Table 1–56, Table 1–57, Table 1–58, Table 1–59, Table 1–60, Table 1–61,
Table 1–62, Table 1–63, Table 1–68, Table 1–69, Table 1–74, Table 1–75,
Table 1–80, Table 1–81, Table 1–86, Table 1–87, Table 1–92, Table 1–93,
Table 1–94, Table 1–95, Table 1–96, Table 1–97, Table 1–98, and Table 1–99.
© January 2010
Altera Corporation
Chapter 1: Cyclone III Device Data Sheet
Document Revision History
Table 1–40. Document Revision History
Date
2.0
December 2007
July 2007
June 2007
© January 2010
(Part 2 of 3)
Version
May 2008
October 2007
1–33
1.5
1.4
1.3
1.2
Altera Corporation
Changes Made
■
Updated “Operating Conditions” section and included information on
automotive device.
■
Updated Table 1–3, Table 1–6, and Table 1–7, and added automotive
information.
■
Under “Pin Capacitance” section, updated Table 1–9 and Table 1–10.
■
Added new “Schmitt Trigger Input” section with Table 1–12.
■
Under “I/O Standard Specifications” section, updated Table 1–13, 1–12 and
1–12.
■
Under “Switching Characteristics” section, updated Table 1–19, 1–15, 1–16,
1–16, 1–17, 1–18, 1–19, 1–20, 1–21, 1–21, 1–23, 1–23, 1–23, 1–24, and
1–25.
■
Updated Figure 1–5 and 1–29.
■
Deleted previous Table 1-35 “DDIO Outputs Half-Period Jitter”.
■
Under “I/O Timing” section, updated Table 1–38, 1–29, 1–32, 1–33, 1–26,
and 1–26.
■
Under “Typical Design Performance” section updated Table 1–46 through
1–145.
■
Under “Core Performance Specifications”, updated Tables 1-18 and 1-19.
■
Under “Preliminary, Correlated, and Final Timing”, updated Table 1-37.
■
Under “Typical Design Performance”, updated Tables 1-45, 1-46, 1-51, 1-52,
1-57, 1-58, Tables 1-63 through 1-68. 1-69, 1-70, 1-75, 1-76, 1-81, 1-82,
Tables 1-87 through 1-92, Tables 1-99, 1-100, 1-107, and 1-108.
■
Updated the CVREFTB value in Table 1-9.
■
Updated Table 1-21.
■
Under “High-Speed I/O Specification” section, updated Tables 1-25 through
1-30.
■
Updated Tables 1-31 through 1-38.
■
Added new Table 1-32.
■
Under “Maximum Input and Output Clock Toggle Rate” section, updated
Tables 1-40 through 1-42.
■
Under “IOE Programmable Delay” section, updated Tables 1-43 through 144.
■
Under “User I/O Pin Timing Parameters” section, updated Tables 1-45
through 1-92.
■
Under “Dedicated Clock Pin Timing Parameters” section, updated Tables 1-93
through 1-108.
■
Updated Table 1-1 with VESDHBM and VES DCDM information.
■
Updated RCONF _PD information in Tables 1-10.
■
Added Note (3) to Table 1-12.
■
Updated tDLOC K information in Table 1-19.
■
Updated Table 1-43 and Table 1-44.
■
Added “Document Revision History” section.
Updated Cyclone III graphic in cover page.
Cyclone III Device Handbook, Volume 2
1–34
Chapter 1: Cyclone III Device Data Sheet
Document Revision History
Table 1–40. Document Revision History
Date
May 2007
March 2007
(Part 3 of 3)
Version
Changes Made
■
Corrected current unit in Tables 1-1, 1-12, and 1-14.
■
Added Note (3) to Table 1-3.
■
Updated Table 1-4 with IC CINT0, I CCA 0, I CCD_P LL0, and IC CIO0 information.
■
Updated Table 1-9 and added Note (2).
■
Updated Table 1-19.
■
Updated Table 1-22 and added Note (1).
■
Changed I/O standard from 1.5-V LVTTL/LVCMOS and 1.2-V LVTTL/LVCMOS
to 1.5-V LVCMOS and 1.2-V LVCMOS in Tables 1-41, 1-42, 1-43, 1-44, and 145.
■
Updated Table 1-43 with changes to LVPEC and LVDS and added Note (5).
■
Updated Tables 1-46, 1-47, Tables 1-54 through 1-95, and Tables 1-98
through 1-111.
■
Removed speed grade –6 from Tables 1-90 through 1-95, and from Tables 1110 through 1-111.
■
Added a waveform (Receiver Input Waveform) in glossary under letter “R”
(Table 1-112).
1.1
1.0
Cyclone III Device Handbook, Volume 2
Initial release.
© January 2010
Altera Corporation