µPD720113 - Renesas Electronics

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DATA SHEET
MOS INTEGRATED CIRCUIT
µPD720113
USB 2.0 HUB CONTROLLER
The µPD720113 is a USB 2.0 hub device that complies with the Universal Serial Bus (USB) Specification Revision
2.0 and works up to 480 Mbps. USB 2.0 compliant transceivers are integrated for upstream and all downstream ports.
The µPD720113 works backward compatible either when any one of the downstream ports is connected to a USB 1.1
compliant device, or when the upstream port is connected to a USB 1.1 compliant host.
Detailed function descriptions are provided in the following user’s manual. Be sure to read the manual before designing.
µPD720113 User’s Manual: S16619E
FEATURES
• Compliant with Universal Serial Bus Specification Revision 2.0 (Data Rate 1.5/12/480 Mbps)
• Certified by USB implementers forum and granted the USB 2.0 high-speed Logo
• High-speed or full-speed packet protocol sequencer for Endpoint 0/1
• 7 (Max.) downstream facing ports
• All downstream facing ports can handle high-speed (480 Mbps), full-speed (12 Mbps), and low-speed (1.5
Mbps) transaction.
• Supports split transaction to handle full-speed and low-speed transaction on downstream facing ports when
Hub controller is working in high-speed mode.
• One Transaction Translator per Hub and supports four non-periodic buffers
• Support self-powered mode
• Supports Over-current detection and Individual or ganged power control
• Supports configurable vendor ID, product ID, string descriptors and others with external Serial ROM
• Supports “non-removable” attribution on individual port
• Uses 30 MHz X’tal, or clock input
• 2.5 V and 3.3 V power supplies
The information in this document is subject to change without notice. Before using this document, please
confirm that this is the latest version.
Not all products and/or types are available in every country. Please check with an NEC Electronics
sales representative for availability and additional information.
Document No. S16618EJ3V0DS00 (3rd edition)
Date Published March 2005 NS CP (N)
Printed in Japan
The mark
shows major revised points.
2003
µPD720113
ORDERING INFORMATION
Part Number
Package
µPD720113GK-9EU
µPD720113GK-9EU-A
Remark
80-pin plastic TQFP (Fine pitch) (12 × 12)
80-pin plastic TQFP (Fine pitch) (12 × 12)
Lead-free product
BLOCK DIAGRAM
To Host/Hub
downstream
facing port
Upstream facing port
UP_PHY
CDR
SERDES
UPC
FS_REP
SIE_2H
CDR
ALL_TT
F_TIM
DP(1)_PHY
EP1
Downstream facing port #1
To Hub/Function
upstream facing port
EP0
DP(2)_PHY
External
Serial ROM
Downstream facing port #2
ROM I/F
To Hub/Function
upstream facing port
DP(3)_PHY
Downstream facing port #3
DPC
APLL
DP(4)_PHY
Downstream facing port #4
X1_CLK/X2
To Hub/Function
upstream facing port
OSB
To Hub/Function
upstream facing port
DP(5)_PHY
Downstream facing port #5
To Hub/Function
upstream facing port
DP(6)_PHY
Downstream facing port #6
To Hub/Function
upstream facing port
DP(7)_PHY
Downstream facing port #7
PPB(7:1)
CSB(7:1)
2
Data Sheet S16618EJ3V0DS
To Hub/Function
upstream facing port
µPD720113
APLL
: Generates all clocks of Hub.
ALL_TT
: Translates the high-speed transactions (split transactions) for full/low-speed device
to full/low-speed transactions.
ALL_TT buffers the data transfer from either
upstream or downstream direction. For OUT transaction, ALL_TT buffers data from
upstream port and sends it out to the downstream facing ports after speed
conversion from high-speed to full/low-speed. For IN transaction, ALL_TT buffers
data from downstream ports and sends it out to the upstream facing ports after
speed conversion from full/low-speed to high-speed.
CDR
: Data & clock recovery circuit
DPC
: Downstream Port Controller handles Port Reset, Enable, Disable, Suspend and
DP(n)_PHY
: Downstream transceiver supports high-speed (480 Mbps), full-speed (12 Mbps), and
EP0
: Endpoint 0 controller
Resume
low-speed (1.5 Mbps) transaction
EP1
: Endpoint 1 controller
F_TIM (Frame Timer)
: Manages hub’s synchronization by using micro-SOF which is received at upstream
port, and generates SOF packet when full/low-speed device is attached to
downstream facing port.
FS_REP
: Full/low-speed repeater is enabled when the µPD720113 are worked at full-speed
mode
OSB
: Oscillator Block
ROM I/F
: Interface block for external Serial ROM which contains user-defined descriptors
SERDES
: Serializer and Deserializer
SIE_2H
: Serial Interface Engine (SIE) controls USB2.0 and 1.1 protocol sequencer.
UP_PHY
: Upstream Transceiver supports high-speed (480 Mbps), full-speed (12 Mbps)
transaction
UPC
: Upstream Port Controller handles Suspend and Resume
Data Sheet S16618EJ3V0DS
3
µPD720113
PIN CONFIGURATION (TOP VIEW)
• 80-pin plastic TQFP (Fine pitch) (12 × 12)
DP5
DM5
VSS
VDD25
DP4
DM4
VSS
VDD25
VSS
VDD33
DP3
DM3
VSS
VDD33
DP2
DM2
VSS
VDD25
DP1
DM1
µPD720113GK-9EU
µPD720113GK-9EU-A
80
VDD33
VDD25
VSS
DM6
DP6
VDD33
VSS
DM7
DP7
VSS
VDD25
VSS
TEST
SCAN_MODE
VSS
LPWRM
EXROM_EN
SCL
SDA/GANG_B
VSS
75
70
65
61
60
1
5
55
10
50
15
45
41
20
25
30
35
40
VDD33
CSB7
PPB7
CSB6
PPB6
CSB5
PPB5
CSB4
VSS
VDD25
PPB4
CSB3
PPB3
CSB2
PPB2
CSB1
PPB1
SYSRSTB
VBUSM
VDD33
21
4
Data Sheet S16618EJ3V0DS
VDD33
RPU
VSS
VDD25
DPU
DMU
VSS
VDD33
VDD25
VSS
AVDD
AVSS
AVDD
AVSS(R)
RREF
AVSS
VDD25
X2
X1_CLK
VSS
µPD720113
Pin No.
Pin Name
Pin No.
Pin Name
Pin No.
Pin Name
Pin No.
Pin Name
1
VDD33
21
VDD33
41
VSS
61
DM1
2
VDD25
22
CSB7
42
X1_CLK
62
DP1
3
VSS
23
PPB7
43
X2
63
VDD25
4
DM6
24
CSB6
44
VDD25
64
VSS
5
DP6
25
PPB6
45
AVSS
65
DM2
6
VDD33
26
CSB5
46
RREF
66
DP2
7
VSS
27
PPB5
47
AVSS(R)
67
VDD33
8
DM7
28
CSB4
48
AVDD
68
VSS
9
DP7
29
VSS
49
AVSS
69
DM3
10
VSS
30
VDD25
50
AVDD
70
DP3
11
VDD25
31
PPB4
51
VSS
71
VDD33
12
VSS
32
CSB3
52
VDD25
72
VSS
13
TEST
33
PPB3
53
VDD33
73
VDD25
14
SCAN_MODE
34
CSB2
54
VSS
74
VSS
15
VSS
35
PPB2
55
DMU
75
DM4
16
LPWRM
36
CSB1
56
DPU
76
DP4
17
EXROM_EN
37
PPB1
57
VDD25
77
VDD25
18
SCL
38
SYSRSTB
58
VSS
78
VSS
19
SDA/GANG_B
39
VBUSM
59
RPU
79
DM5
20
VSS
40
VDD33
60
VDD33
80
DP5
Remark AVSS(R) should be used to connect RREF through 1 % precision reference resistor of 2.43 kΩ.
Data Sheet S16618EJ3V0DS
5
µPD720113
1.
PIN INFORMATION
Pin Name
I/O
Buffer Type
Active
Function
Level
X1_CLK
I
2.5 V Input
Crystal oscillator in or clock input
X2
O
2.5 V Output
Oscillator out
SYSRSTB
I
5 V tolerant Schmitt Input
RPU
A (O)
Low
Asynchronous chip reset
USB Pull-up control
External 1.5 kΩ pull-up resistor control
DP(7:1)
I/O
USB D+ signal I/O
USB’s downstream facing port D+ signal
DM(7:1)
I/O
USB D− signal I/O
USB’s downstream facing port D− signal
DPU
I/O
USB D+ signal I/O
USB’s upstream facing port D+ signal
DMU
I/O
USB D− signal I/O
USB’s upstream facing port D− signal
I
3.3 V Schmitt Input
Local power monitor
Analog
Reference resistor
LPWRM
RREF
A (O)
CSB(7:1)
I
5 V tolerant Input
Low
Port’s over-current status input
PPB(7:1)
O
5 V tolerant N-ch open drain
Low
Port’s power supply control output
VBUSM
I
5 V tolerant Schmitt input
VBUS monitor
SCL
O
3.3 V Output
External serial ROM clock out
SDA/GANG_B
I/O
3.3 V Schmitt I/O
External serial ROM data IO or power
management mode select
EXROM_EN
I
3.3 V Schmitt Input
External serial ROM input enable
TEST
I
3.3 V Input
Test signal
SCAN_MODE
I
3.3 V Input
Test signal
VDD33
3.3 V VDD
VDD25
2.5 V VDD
AVDD
2.5 V VDD for analog circuit
VSS
VSS
AVSS
VSS for analog circuit
AVSS(R)
VSS for reference resistor. Connect to AVSS.
Remark “5 V tolerant“ means that the buffer is 3 V buffer with 5 V tolerant circuit.
6
Data Sheet S16618EJ3V0DS
µPD720113
2.
ELECTRICAL SPECIFICATIONS
2.1
Buffer List
•
2.5 V Oscillator interface
•
5 V Schmitt input buffer
•
3.3 V Schmitt input buffer
•
3.3 V input buffer
•
3.3 V IOL = 3 mA bi-directional Schmitt input buffer with input enable (OR-type)
•
3.3 V IOL = 3 mA output buffer
•
5 V IOL = 12 mA N-ch open drain buffer
•
USB2.0 interface
X1_CLK, X2
SYSRSTB, CSB(7:1), VBUSM
LPWRM
EXROM_EN, TEST, SCAN_MODE
SDA/GANG_B
SCL
PPB(7:1)
RPU, DPU, DMU, DP(7:1), DM(7:1), RREF
Above, “5 V” refers to a 3 V input buffer that is 5 V tolerant (has 5 V maximum input voltage). Therefore, it is
possible to have a 5 V connection for an external bus.
Data Sheet S16618EJ3V0DS
7
µPD720113
2.2
Terminology
Terms Used in Absolute Maximum Ratings
Parameter
Power supply voltage
Input voltage
Symbol
Meaning
VDD33
Indicates voltage range within which damage or reduced reliability will not
VDD25
AVDD
result when power is applied to a VDD pin.
VI
Indicates voltage range within which damage or reduced reliability will not
result when power is applied to an input pin.
Output voltage
VO
Indicates voltage range within which damage or reduced reliability will not
result when power is applied to an output pin.
Output current
IO
Indicates absolute tolerance values for DC current to prevent damage or
reduced reliability when current flows out of or into an output pin.
Operating temperature
TA
Storage temperature
Tstg
Indicates the ambient temperature range for normal logic operations.
Indicates the element temperature range within which damage or reduced
reliability will not result while no voltage or current are applied to the device.
Terms Used in Recommended Operating Range
Parameter
Power supply voltage
High-level input voltage
Symbol
Meaning
VDD33
Indicates the voltage range for normal logic operations to occur when VSS = 0
VDD25
AVDD
V.
VIH
Indicates the voltage, applied to the input pins of the device, which indicates
the high level state for normal operation of the input buffer.
* If a voltage that is equal to or greater than the “MIN.” value is applied, the
input voltage is guaranteed as high level voltage.
Low-level input voltage
VIL
Indicates the voltage, applied to the input pins of the device, which indicates
the low level state for normal operation of the input buffer.
* If a voltage that is equal to or less than the “MAX.” value is applied, the
input voltage is guaranteed as low level voltage.
8
Hysteresis voltage
VH
Indicates the differential between the positive trigger voltage and the negative
trigger voltage.
Input rise time
tri
Indicates allowable input signal transition time from 0.1 × VDD to 0.9 × VDD.
Input fall time
tfi
Indicates allowable input signal transition time from 0.9 × VDD to 0.1 × VDD.
Data Sheet S16618EJ3V0DS
µPD720113
Terms Used in DC Characteristics
Parameter
Off-state output leakage current
Symbol
IOZ
Meaning
Indicates the current that flows into a 3-state output pin when it is in a highimpedance state and a voltage is applied to the pin.
Output short circuit current
IOS
Indicates the current that flows from an output pin when it is shorted to GND
while it is at high-level.
Input leakage current
II
Indicates the current that flows into an input pin when a voltage is applied to
the pin.
Low-level output current
IOL
Indicates the current that can flow into an output pin in the low-level state
without raising the output voltage above the specified VOL.
High-level output current
IOH
Indicates the current that can flow out of an output pin in the high-level state
without reducing the output voltage below the specified VOH. (A negative
current indicates current flowing out of the pin.)
2.3
Electrical Specifications
Absolute Maximum Ratings
Parameter
Power supply voltage
Input/output voltage
Symbol
Condition
Rating
Unit
VDD33
−0.5 to +4.6
V
VDD25
−0.5 to +3.6
V
AVDD
−0.5 to +3.6
V
−0.5 to +3.6
V
−0.5 to +4.6
V
−0.5 to +6.6
V
IOL = 3 mA
10
mA
IOL = 6 mA
IOL = 12 mA
20
40
mA
mA
VI/VO
2.3 V ≤ VDD25 ≤ 2.7 V
2.5 V input/output voltage
VI /VO < VDD25 + 0.9 V
3.0 V ≤ VDD33 ≤ 3.6 V
3.3 V input/output voltage
VI /VO < VDD33 + 1.0 V
3.0 V ≤ VDD33 ≤ 3.6 V
5 V input/out voltage
VI /VO < VDD33 + 3.0 V
Output current
IO
Operating temperature
TA
0 to +70
°C
Storage temperature
Tstg
−65 to +150
°C
Caution Product quality may suffer if the absolute maximum rating is exceeded even momentarily for any
parameters. That is, the absolute maximum ratings are rated values at which the product is on the
verge of suffering physical damage, and therefore the product must be used under conditions
that ensure that the absolute maximum ratings are not exceeded.
The ratings and conditions indicated for DC characteristics and AC characteristics represent the
quality assurance range during normal operation.
Data Sheet S16618EJ3V0DS
9
µPD720113
Recommended Operating Ranges
Parameter
Operating voltage
High-level input voltage
Symbol
Condition
MIN.
TYP.
MAX.
Unit
VDD33
3.3 V for VDD33 pins
3.14
3.30
3.46
V
VDD25
2.5 V for VDD25 pins
2.3
2.5
2.7
V
AVDD
2.5 V for AVDD pins
2.3
2.5
2.7
V
VIH
2.5 V High-level input voltage
1.7
VDD25
V
3.3 V High-level input voltage
2.0
VDD33
V
5.0 V High-level input voltage
2.0
5.5
V
2.5 V Low-level input voltage
0
0.7
V
3.3 V Low-level input voltage
0
0.8
V
5.0 V Low-level input voltage
0
0.8
V
5 V Hysteresis voltage
0.3
1.5
V
3.3 V Hysteresis voltage
0.2
1.0
V
10
ms
Low-level input voltage
Hysteresis voltage
VIL
VH
Input rise time for SYSRSTB
trst
Input rise time
tri
Normal buffer
0
200
ns
Schmitt buffer
0
10
ms
Normal buffer
0
200
ns
Schmitt buffer
0
10
ms
Input fall time
tfi
Two power supply rails limitation.
The µPD720113 has two power supply rails (2.5 V, 3.3 V). The system will require the time when power supply
rail is stable at VDD level. And, there will be difference between the time of VDD25 and VDD33. The µPD720113
requires that VDD25 should be stable before VDD33 becomes stable. At any case, the system must ensure that the
absolute maximum ratings for VI /VO are not exceeded. System reset signaling should be asserted more than
specified time after both VDD25 and VDD33 are stable.
10
Data Sheet S16618EJ3V0DS
µPD720113
DC Characteristics
Parameter
Off-state output leakage current
Symbol
IOZ
Output short circuit current
IOS
Low-level output current
IOL
Condition
MIN.
VO = VDD33, VDD25 or VSS
Note
MAX.
Unit
±10
µA
−250
mA
3.3 V low-level output current
VOL = 0.4 V
3
mA
3.3 V low-level output current
VOL = 0.4 V
6
mA
5.0 V low-level output current
VOL = 0.4 V
12
mA
3.3 V high-level output current
VOH = 2.4 V
−3
mA
3.3 V high-level output current
VOH = 2.4 V
−6
mA
5.0 V high-level output current
VOH = 2.4 V
−2
mA
High-level output current
Input leakage current
IOH
II
3.3 V buffer
VI = VDD or VSS
±10
µA
5.0 V buffer
VI = VDD or VSS
±10
µA
Note The output short circuit time is measured at one second or less and is tested with only one pin on the LSI.
Data Sheet S16618EJ3V0DS
11
µPD720113
USB Interface Block
Parameter
Symbol
Conditions
Includes RS resistor
MIN
MAX
Unit
40.5
49.5
Ω
Output pin impedance
ZHSDRV
Bus pull-up resistor on upstream facing
port
RPU
1.425
1.575
kΩ
Bus pull-up resistor on downstream
facing port
RPD
14.25
15.75
kΩ
Termination voltage for upstream facing
port pullup (full-speed)
VTERM
3.0
3.6
V
High-level input voltage (drive)
VIH
2.0
High-level input voltage (floating)
VIHZ
2.7
Low-level input voltage
VIL
Differential input sensitivity
VDI
(D+) − (D−)
0.2
Differential common mode range
VCM
Includes VDI range
0.8
2.5
V
High-level output voltage
VOH
RL of 14.25 kΩ to GND
2.8
3.6
V
Low-level output voltage
VOL
RL of 1.425 kΩ to 3.6 V
0.0
0.3
V
SE1
VOSE1
0.8
Output signal crossover point voltage
VCRS
1.3
2.0
V
High-speed squelch detection threshold
(differential signal)
VHSSQ
100
150
mV
High-speed disconnect detection
threshold (differential signal)
VHSDSC
525
625
mV
High-speed data signaling common
mode voltage range
VHSCM
−50
+500
mV
High-speed differential input signaling
levels
See Figure 2-4.
Input Levels for Low-/full-speed:
V
3.6
V
0.8
V
V
Output Levels for Low-/full-speed:
V
Input Levels for High-speed:
Output Levels for High-speed:
High-speed idle state
VHSOI
−10.0
+10
mV
High-speed data signaling high
VHSOH
360
440
mV
High-speed data signaling low
VHSOL
−10.0
+10
mV
Chirp J level (different signal)
VCHIRPJ
700
1100
mV
Chirp K level (different signal)
VCHIRPK
−900
−500
mV
12
Data Sheet S16618EJ3V0DS
µPD720113
Figure 2-1. Differential Input Sensitivity Range for Low-/full-speed
Differential Input Voltage Range
Differential Output
Crossover
Voltage Range
0.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
4.6
Input Voltage Range (Volts)
Figure 2-2. Full-speed Buffer VOH/IOH Characteristics for High-speed Capable Transceiver
VDD−3.3
VDD−2.8 VDD−2.3
VDD−1.8 VDD−1.3 VDD−0.8
VDD−0.3 VDD
0
IOUT (mA)
−20
−40
Min.
−60
Max.
−80
VOUT (V)
Figure 2-3. Full-speed Buffer VOL/IOL Characteristics for High-speed Capable Transceiver
80
Max.
60
IOUT (mA)
-1.0
Min.
40
20
0
0
0.5
1
1.5
2
2.5
3
VOUT (V)
Data Sheet S16618EJ3V0DS
13
µPD720113
Figure 2-4. Receiver Sensitivity for Transceiver at DP/DM
Level 1
+400 mV
Differential
Point 3
Point 1
Point 4
0V
Differential
Point 2
Point 5
Point 6
−400 mV
Differential
Level 2
Unit Interval
0%
100%
Figure 2-5. Receiver Measurement Fixtures
Test Supply Voltage
15.8 Ω
USB
Connector
Nearest
Device
VBUS
D+
DGND
15.8 Ω
143 Ω
14
50 Ω
Coax
50 Ω
Coax
143 Ω
Data Sheet S16618EJ3V0DS
+
To 50 Ω Inputs of a
High Speed Differential
Oscilloscope, or 50 Ω
Outputs of a High Speed
Differential Data Generator
−
µPD720113
Power Consumption
Parameter
Power Consumption
Symbol
PW-0
Condition
Unit
The power consumption under the state without suspend.
All the ports do not connect to any function.
Note
Hub controller is operating at full-speed mode.
Hub controller is operating at high-speed mode.
PW-5
TYP.
44
mA (2.5 V)
2.2
mA (3.3 V)
84
23
mA (2.5 V)
mA (3.3 V)
The power consumption under the state without suspend.
The number of active ports is 5.
Hub controller is operating at full-speed mode.
44
mA (2.5 V)
8.9
mA (3.3 V)
138
85
mA (2.5 V)
mA (3.3 V)
44
mA (2.5 V)
10
mA (3.3 V)
148
98
mA (2.5 V)
mA (3.3 V)
44
mA (2.5 V)
12
mA (3.3 V)
158
111
mA (2.5 V)
mA (3.3 V)
The power consumption under suspend state.
0.68
mA (2.5 V)
The internal clock is stopped.
0.24
mA (3.3 V)
Hub controller is operating at high-speed mode.
PW-6
The power consumption under the state without suspend.
The number of active ports is 6.
Hub controller is operating at full-speed mode.
Hub controller is operating at high-speed mode.
PW-7
The power consumption under the state without suspend.
The number of active ports is 7.
Hub controller is operating at full-speed mode.
Hub controller is operating at high-speed mode.
PW_S
Note
When any device is not connected to all the ports, the power consumption does not depend on the number
of active ports.
Data Sheet S16618EJ3V0DS
15
µPD720113
System Clock Ratings
Parameter
Clock frequency
Symbol
fCLK
Condition
X’tal
MIN.
TYP.
MAX.
Unit
−500
30
+500
MHz
ppm
Oscillator block
Clock Duty cycle
tDUTY
ppm
−500
ppm
30
+500
ppm
MHz
40
50
60
%
Remarks 1. Recommended accuracy of clock frequency is ± 100 ppm.
2. Required accuracy of X’tal or oscillator block is including initial frequency accuracy, the spread of
X’tal capacitor loading, supply voltage, temperature, and aging, etc.
AC Characteristics (VDD = 3.14 to 3.46 V, TA = 0 to +70°C)
System Reset Timing
Parameter
Reset active time (Figure 2-6)
Symbol
Conditions
trst
5
Figure 2-6. System Reset Timing
trst
SYSRSTB
16
MIN.
Data Sheet S16618EJ3V0DS
MAX.
Unit
µs
µPD720113
Over-current Response Timing
Parameter
Symbol
Over-current response time from CSB
Condition
MIN.
tOC
TYP.
500
MAX.
Unit
625
µs
low to PPB high (Figure 2-7)
Figure 2-7. Over-current Response Timing
CSB(7:1)
tOC
PPB(7:1)
Figure 2-8. CSB/PPB Timing
500 µs
Hub power supply
500 µs
500 µs
500 µs
Bus reset
Up port D+ line
PPB pin output
CSB pin input
Output
cut-off
Port power
supply ON
Device
connection
inrush current
Overcurrent
generation
CSB pin operation region
Bus power: Up port connection
Self power: Power supply ON
Remark
CSB detection
delay time
CSB active
period
The active period of the CSB pin is in effect only when the PPB pin is ON.
There is a delay time of approximately 500 µs duration at the CSB pin.
Data Sheet S16618EJ3V0DS
17
µPD720113
External Serial ROM Timing
Parameter
Symbol
Condition
MIN.
TYP.
MAX.
Unit
94.6
100
kHz
Clock frequency
fSCL
Clock pulse width low
tLOW
4700
ns
Clock pulse width high
tHIGH
4000
ns
Clock low to data out valid
tAA
100
Time the bus must be free before a new
transmission can start
tBUF
4700
ns
Start hold time
tHD.STA
4000
ns
Start setup time
tSU.STA
4700
ns
Data in hold time
tHD.DTA
0
ns
Data in setup time
tSU.DTA
250
ns
Stop setup time
tSU.STO
4700
ns
Data out hold time
tDH
300
ns
Write cycle time
tWR
3500
15
Figure 2-9. External Serial ROM Bus Timing
tHIGH
tLOW
tLOW
SCL
tSU.STA
tHD.STA
tHD.DAT
tSU.DAT
tSU.STO
SDA
(Output)
tAA
tDH
tBUF
SDA
(Input)
Figure 2-10. External Serial ROM Write Cycle Timing
SCL
8th bit
SDA
ACK
Word n
tWR
Stop
condition
18
Data Sheet S16618EJ3V0DS
Start
condition
ns
ms
µPD720113
USB Interface Block
(1/4)
Parameter
Symbol
Conditions
MIN.
MAX.
Unit
Low-speed Electrical Characteristics
Rise time (10% to 90%)
tLR
CL = 200 pF to 600 pF
75
300
ns
Fall time (90% to 10%)
tLF
CL = 200 pF to 600 pF
75
300
ns
80
125
%
1.49925
1.50075
Mbps
tDDJ1
tDDJ2
−25
−14
+25
+14
ns
ns
tUJR1
tUJR2
−152
−200
+152
+200
ns
ns
Source SE0 interval of EOP (Figure 2-16)
tLEOPT
1.25
1.5
µs
Receiver SE0 interval of EOP (Figure 2-16)
tLEOPR
670
Note
Differential rise and fall time matching
tLRFM
(tLR/tLF)
Low-speed data rate
tLDRATHS
Average bit rate
Downstream facing port source jitter total
(including frequency tolerance) (Figure
2-15):
To next transition
For paired transitions
Downstream facing port differential
receiver jitter total (including frequency
tolerance) (Figure 2-17):
To next transition
For paired transitions
ns
Width of SE0 interval during differential
transition
tLST
210
ns
Hub differential data delay (Figure 2-13)
tLHDD
300
ns
Hub differential driver jitter (including cable)
(Figure 2-13):
Downstream facing port
To next transition
For paired transitions
tLDHJ1
tLDHJ2
−45
−15
+45
+15
ns
ns
tLUHJ1
tLUHJ2
−45
−45
+45
+45
ns
ns
tLSOP
−60
+60
ns
tLEOPD
0
200
ns
tLHESK
−300
+300
ns
4
20
ns
4
20
ns
90
111.11
%
11.9940
12.0060
Mbps
0.9995
1.0005
ms
Upstream facing port
To next transition
For paired transitions
Data bit width distortion after SOP (Figure
2-13)
Hub EOP delay relative to tHDD (Figure
2-14)
Hub EOP output width skew (Figure 2-14)
Full-speed Electrical Characteristics
Rise time (10% to 90%)
tFR
CL = 50 pF,
RS = 36 Ω
Fall time (90% to 10%)
tFF
CL = 50 pF,
RS = 36 Ω
Differential rise and fall time matching
tFRFM
(tFR/tFF)
Full-speed data rate
tFDRATHS
Average bit rate
Frame interval
tFRAME
Note Excluding the first transition from the Idle state.
Data Sheet S16618EJ3V0DS
19
µPD720113
(2/4)
Parameter
Symbol
Conditions
MIN.
MAX.
Unit
42
ns
−3.5
−4.0
+3.5
+4.0
ns
ns
−2
+5
ns
−18.5
−9
+18.5
+9
ns
ns
175
ns
Full-speed Electrical Characteristics (Continued)
Consecutive frame interval jitter
tRFI
No clock adjustment
Note
Source jitter total (including frequency
tolerance) (Figure 2-15):
To next transition
For paired transitions
Source jitter for differential transition to
SE0 transition (Figure 2-16)
tDJ1
tDJ2
tFDEOP
Receiver jitter (Figure 2-17):
To Next Transition
For Paired Transitions
tJR1
tJR2
Source SE0 interval of EOP (Figure 2-16)
tFEOPT
160
Receiver SE0 interval of EOP (Figure 2-16)
tFEOPR
82
Width of SE0 interval during differential
transition
tFST
14
ns
tHDD1
tHDD2
70
44
ns
ns
ns
Hub differential data delay (Figure 2-13)
(with cable)
(without cable)
Hub differential driver jitter (including cable)
(Figure 2-13):
tHDJ1
tHDJ2
−3
−1
+3
+1
ns
ns
Data bit width distortion after SOP (Figure
2-13)
tFSOP
−5
+5
ns
Hub EOP delay relative to tHDD (Figure
2-14)
tFEOPD
0
15
ns
Hub EOP output width skew (Figure 2-14)
tFHESK
−15
+15
ns
Rise time (10% to 90%)
tHSR
500
ps
Fall time (90% to 10%)
tHSF
500
ps
Driver waveform
See Figure 2-11.
High-speed data rate
tHSDRAT
479.760
480.240
Mbps
Microframe interval
tHSFRAM
124.9375
125.0625
µs
Consecutive microframe interval difference
tHSRFI
4 highspeed
Bit
times
Data source jitter
See Figure 2-11.
Receiver jitter tolerance
See Figure 2-4.
Hub data delay (without cable)
tHSHDD
36 highspeed+4 ns
Bit
times
Hub data jitter
See Figure 2-4, Figure 2-11.
Hub delay variation range
tHSHDV
5 highspeed
Bit
times
To next transition
For paired transitions
High-speed Electrical Characteristics
Note Excluding the first transition from the Idle state.
20
Data Sheet S16618EJ3V0DS
µPD720113
(3/4)
Parameter
Symbol
Conditions
MIN.
MAX.
Unit
2.5
2.5
2000
12000
µs
µs
2.5
µs
Hub Event Timings
Time to detect a downstream facing port
tDCNN
connect event (Figure 2-19):
Awake hub
Suspended hub
Time to detect a disconnect event at a
hub’s downstream facing port (Figure 2-18)
tDDIS
2.0
Duration of driving resume to a
tDRSMDN
20
ms
downstream port (only from a controlling
hub)
Time from detecting downstream resume
to rebroadcast
tURSM
1.0
ms
Duration of driving reset to a downstream
facing port (Figure 2-20)
tDRST
10
20
ms
Time to detect a long K from upstream
tURLK
2.5
100
µs
Time to detect a long SE0 from upstream
tURLSE0
2.5
10000
µs
Duration of repeating SE0 upstream (for
low-/full-speed repeater)
tURPSE0
23
FS Bit
times
Inter-packet delay (for high-speed) of
packets traveling in same direction
tHSIPDSD
88
Bit
times
Inter-packet delay (for high-speed) of
packets traveling in opposite direction
tHSIPDOD
8
Bit
times
Inter-packet delay for device/root hub
tHSRSPIPD1
Only for a SetPortFeature
(PORT_RESET) request
192
response with detachable cable for highspeed
Time of which a Chirp J or Chirp K must be
tFILT
Bit
times
µs
2.5
continuously detected (filtered) by hub or
device during Reset handshake
Time after end of device Chirp K by which
tWTDCH
100
µs
hub must start driving first Chirp K in the
hub’s chirp sequence
tDCHBIT
40
60
µs
Time before end of reset by which a hub
must end its downstream chirp sequence
tDCHSE0
100
500
µs
Time from internal power good to device
pulling D+ beyond VIHZ (Figure 2-20)
tSIGATT
100
ms
Debounce interval provided by USB
system software after attach (Figure 2-20)
tATTDB
100
ms
Maximum duration of suspend averaging
interval
tSUSAVGI
1
s
Period of idle bus before device can initiate
resume
tWTRSM
5
Duration of driving resume upstream
tDRSMUP
1
Time for which each individual Chirp J or
Chirp K in the chirp sequence is driven
downstream by hub during reset
Data Sheet S16618EJ3V0DS
ms
15
ms
21
µPD720113
(4/4)
Parameter
Symbol
Conditions
MIN.
MAX.
Unit
Hub Event Timings (Continued)
Resume recovery time
tRSMRCY
Remote-wakeup is
enabled
10
Time to detect a reset from upstream for
non high-speed capable devices
tDETRST
Reset recovery time (Figure 2-20)
tRSTRCY
Inter-packet delay for full-speed
tIPD
Inter-packet delay for device response with
detachable cable for full-speed
tRSPIPD1
6.5
Bit
times
SetAddress() completion time
tDSETADDR
50
ms
Time to complete standard request with no
data
tDRQCMPLTND
50
ms
Time to deliver first and subsequent
(except last) data for standard request
tDRETDATA1
500
ms
Time to deliver last data for standard
request
tDRETDATAN
50
ms
Time for which a suspended hub will see a
tFILTSE0
2.5
tWTRSTFS
2.5
3000
ms
tWTREV
3.0
3.125
ms
tWTRSTHS
100
875
ms
tUCH
1.0
2.5
ms
10000
µs
10
ms
2
Bit
times
µs
continuous SE0 on upstream before
beginning the high-speed detection
handshake
Time a hub operating in non-suspended
full-speed will wait after start of SE0 on
upstream before beginning the high-speed
detection handshake
Time a hub operating in high-speed will
wait after start of SE0 on upstream before
reverting to full-speed
Time a hub will wait after reverting to fullspeed before sampling the bus state on
upstream and beginning the high-speed
will wait after start of SE0 on upstream
before reverting to full-speed
Minimum duration of a Chirp K on
ms
upstream from a hub within the reset
protocol
Time after start of SE0 on upstream by
tUCHEND
7.0
ms
Time between detection of downstream
chip and entering high-speed state
tWTHS
500
µs
Time after end of upstream Chirp at which
tWTFS
2.5
ms
which a hub will complete its Chirp K within
the reset protocol
hub reverts to full-speed default state if no
downstream Chirp is detected
22
Data Sheet S16618EJ3V0DS
1.0
µPD720113
Figure 2-11. Transmit Waveform for Transceiver at DP/DM
+400 mV
Differential
Level 1
Point 3
Point 4
Point 1
0V
Differential
Point 2
Point 5
Point 6
−400 mV
Differential
Level 2
Unit Interval
0%
100%
Figure 2-12. Transmitter Measurement Fixtures
Test Supply Voltage
15.8 Ω
USB
Connector
Nearest
Device
VBUS
D+
DGND
15.8 Ω
143 Ω
50 Ω
Coax
50 Ω
Coax
+
To 50 Ω Inputs of a
High Speed Differential
Oscilloscope, or 50 Ω
Outputs of a High Speed
Differential Data Generator
−
143 Ω
Data Sheet S16618EJ3V0DS
23
µPD720113
Timing Diagram
Figure 2-13. Hub Differential Delay, Differential Jitter, and SOP Distortion
Upstream
End of
Cable
Crossover
Point
Upstream
Port of Hub
50% Point of
Initial Swing
VSS
VSS
Downstream
Port of Hub
Hub Delay
Downstream
tHDD1
VSS
50% Point of
Initial Swing
Hub Delay
Downstream
tHDD2
Downstream
Port of Hub
VSS
A. Downstream Hub Delay with Cable
B. Downstream Hub Delay without Cable
Downstream
Port of Hub
Crossover
Point
VSS
Upstream Port
or
End of Cable
Hub Delay
Upstream
tHDD1
tHDD2
VSS
Crossover
Point
C. Upstream Hub Delay with or without Cable
Upstream end of cable
Upstream port
Downstream port
Receptacle
Plug
Host or
Hub
Hub
Function
Downstream signaling
Upstream signaling
D. Measurement Points
Hub Differential Jitter:
tHDJ1 = tHDDx(J) − tHDDx(K) or tHDDx(K) − tHDDx(J) Consecutive Transitions
tHDJ2 = tHDDx(J) − tHDDx(J) or tHDDx(K) − tHDDx(K) Paired Transitions
Bit after SOP Width Distortion (same as data jitter for SOP and next J transition):
tFSOP = tHDDx(next J) − tHDDx(SOP)
Low-speed timings are determined in the same way for:
tLHDD, tLDHJ1, tLDJH2, tLUHJ1, tLUJH2, and tLSOP
24
Data Sheet S16618EJ3V0DS
µPD720113
Figure 2-14. Hub EOP Delay and EOP Skew
Upstream
End of
Cable
50% Point of
Initial Swing
Upstream
Port of Hub
VSS
Crossover
Point
Extended
VSS
tEOP- tEOP+
tEOP- tEOP+
Downstream
Port of Hub
Downstream
Port of Hub
VSS
VSS
A. Downstream EOP Delay with Cable
B. Downstream EOP Delay without Cable
Crossover
Point
Extended
Downstream
Port of Hub
VSS
tEOP-
tEOP+
Crossover
Point
Extended
Upstream Port
or
End of Cable
VSS
C. Upstream EOP Delay with or without Cable
EOP Delay:
tFEOPD = tEOPy − tHDDx
(tEOPy means that this equation applies to tEOP- and tEOP+)
EOP Skew:
tFHESK = tEOP+ − tEOPLow-speed timings are determined in the same way for:
tLEOPD and tLHESK
Data Sheet S16618EJ3V0DS
25
µPD720113
Figure 2-15. USB Differential Data Jitter for Low-/full-speed
tPERIOD
Differential
Data Lines
Crossover
Points
Consecutive
Transitions
N × tPERIOD + txDJ1
Paired
Transitions
N × tPERIOD + txDJ2
Figure 2-16. USB Differential-to-EOP Transition Skew and EOP Width for Low-/full-speed
tPERIOD
Differential
Data Lines
Crossover
Point Extended
Crossover
Point
Diff. Data-toSE0 Skew
N × tPERIOD + txDEOP
Source EOP Width: tFEOPT
tLEOPT
Receiver EOP Width: tFEOPR
tLEOPR
Figure 2-17. USB Receiver Jitter Tolerance for Low-/full-speed
tPERIOD
Differential
Data Lines
txJR
txJR1
Consecutive
Transitions
N × tPERIOD + txJR1
Paired
Transitions
N × tPERIOD + txJR2
26
Data Sheet S16618EJ3V0DS
txJR2
µPD720113
Figure 2-18. Low-/full-speed Disconnect Detection
D+/D−
VIHZ (min)
VIL
D−/D+
VSS
tDDIS
Device
Disconnected
Disconnect
Detected
Figure 2-19. Full-/high-speed Device Connect Detection
D+
VIH
D−
VSS
tDCNN
Device
Connected
Connect
Detected
Figure 2-20. Power-on and Connection Events Timing
Hub port
power OK
Reset recovery
time
Attatch detected
Hub port
power-on
≥ 4.01 V
t2SUSP
VBUS
VIH (min)
VIH
D+
or
D−
∆t1
tSIGATT
tATTDB
Data Sheet S16618EJ3V0DS
tDRST
USB system software
reads device speed
tRSTRCY
27
µPD720113
3.
PACKAGE DRAWING
80-PIN PLASTIC TQFP (FINE PITCH) (12x12)
HD
D
60
detail of lead end
41
61
40
A
A2
A3
E
HE
θ
L
Lp
A1
80
21
1
20
(UNIT:mm)
ZE
ZD
b
x
e
M
L1
S
y
S
NOTE
Each lead centerline is located within 0.08 mm of
its true position at maximum material condition.
c
ITEM
D
DIMENSIONS
12.00±0.20
E
12.00±0.20
A2
1.00
HD
14.00±0.20
HE
14.00±0.20
A
1.10±0.10
A1
0.10±0.05
A3
0.25
Lp
0.60±0.15
b
0.22±0.05
c
0.17 +0.03
−0.07
θ
3° +4°
−3°
e
0.50
x
0.08
y
0.08
ZD
1.25
ZE
1.25
L
0.50
L1
28
Data Sheet S16618EJ3V0DS
1.00±0.20
K80GK-50-9EU
µPD720113
4.
RECOMMENDED SOLDERING CONDITIONS
The µPD720113 should be soldered and mounted under the following recommended conditions.
For soldering methods and conditions other than those recommended below, contact an NEC Electronics sales
representative.
For technical information, see the following website.
Semiconductor Device Mount Manual (http://www.necel.com/pkg/en/mount/index.html)
µPD720113GK-9EU:
80-pin plastic TQFP (Fine pitch) (12 × 12)
Soldering Method
Infrared reflow
Soldering Conditions
Package peak temperature: 235°C, Time: 30 seconds max. (at 210°C or higher),
Symbol
IR35-103-3
Count: Three times or less
Exposure limit: 3 days
Partial heating
Note
(after that, prebake at 125°C for 10 hours)
Pin temperature: 300°C max., Time: 3 seconds max. (per pin row)
–
Note After opening the dry pack, store it at 25°C or less and 65% RH or less for the allowable storage period.
µPD720113GK-9EU-A:
80-pin plastic TQFP (Fine pitch) (12 × 12) Lead-free product
Soldering Method
Infrared reflow
Soldering Conditions
Package peak temperature: 245°C, Time: 60 seconds max. (at 220°C or higher),
Symbol
IR45-107-3
Count: Three times or less
Exposure limit: 7 days
Partial heating
Note
(after that, prebake at 125°C for 10 hours)
Pin temperature: 300°C max., Time: 3 seconds max. (per pin row)
–
Note After opening the dry pack, store it at 25°C or less and 65% RH or less for the allowable storage period.
Data Sheet S16618EJ3V0DS
29
µPD720113
[MEMO]
30
Data Sheet S16618EJ3V0DS
µPD720113
NOTES FOR CMOS DEVICES
1
VOLTAGE APPLICATION WAVEFORM AT INPUT PIN
Waveform distortion due to input noise or a reflected wave may cause malfunction. If the input of the
CMOS device stays in the area between VIL (MAX) and VIH (MIN) due to noise, etc., the device may
malfunction. Take care to prevent chattering noise from entering the device when the input level is fixed,
and also in the transition period when the input level passes through the area between VIL (MAX) and
VIH (MIN).
2
HANDLING OF UNUSED INPUT PINS
Unconnected CMOS device inputs can be cause of malfunction. If an input pin is unconnected, it is
possible that an internal input level may be generated due to noise, etc., causing malfunction. CMOS
devices behave differently than Bipolar or NMOS devices. Input levels of CMOS devices must be fixed
high or low by using pull-up or pull-down circuitry. Each unused pin should be connected to VDD or GND
via a resistor if there is a possibility that it will be an output pin. All handling related to unused pins must
be judged separately for each device and according to related specifications governing the device.
3
PRECAUTION AGAINST ESD
A strong electric field, when exposed to a MOS device, can cause destruction of the gate oxide and
ultimately degrade the device operation. Steps must be taken to stop generation of static electricity as
much as possible, and quickly dissipate it when it has occurred.
Environmental control must be
adequate. When it is dry, a humidifier should be used. It is recommended to avoid using insulators that
easily build up static electricity. Semiconductor devices must be stored and transported in an anti-static
container, static shielding bag or conductive material. All test and measurement tools including work
benches and floors should be grounded.
The operator should be grounded using a wrist strap.
Semiconductor devices must not be touched with bare hands. Similar precautions need to be taken for
PW boards with mounted semiconductor devices.
4
STATUS BEFORE INITIALIZATION
Power-on does not necessarily define the initial status of a MOS device. Immediately after the power
source is turned ON, devices with reset functions have not yet been initialized. Hence, power-on does
not guarantee output pin levels, I/O settings or contents of registers. A device is not initialized until the
reset signal is received. A reset operation must be executed immediately after power-on for devices
with reset functions.
5
POWER ON/OFF SEQUENCE
In the case of a device that uses different power supplies for the internal operation and external
interface, as a rule, switch on the external power supply after switching on the internal power supply.
When switching the power supply off, as a rule, switch off the external power supply and then the
internal power supply. Use of the reverse power on/off sequences may result in the application of an
overvoltage to the internal elements of the device, causing malfunction and degradation of internal
elements due to the passage of an abnormal current.
The correct power on/off sequence must be judged separately for each device and according to related
specifications governing the device.
6
INPUT OF SIGNAL DURING POWER OFF STATE
Do not input signals or an I/O pull-up power supply while the device is not powered. The current
injection that results from input of such a signal or I/O pull-up power supply may cause malfunction and
the abnormal current that passes in the device at this time may cause degradation of internal elements.
Input of signals during the power off state must be judged separately for each device and according to
related specifications governing the device.
Data Sheet S16618EJ3V0DS
31
µPD720113
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• The information in this document is current as of March, 2005. The information is subject to change
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M8E 02. 11-1