SMSC TMC2005

TMC2005-JT
ARCNET 5 Port HUB Controller
FEATURES
ƒ
ƒ
ƒ
ƒ
ARCNET HUB Circuit for ARCNET Protocol
(Data Rate From 156.25Kbps to 10Mbps)
Able to Connect Various Transceivers Directly
Device Includes TX/RX Timing Circuit for 5 Port
Hub and Direction Control Circuit, Jitter Correct
Circuit and Noise Cancel Circuit
Easy to Design 8 or 12 Port Hub
ƒ
ƒ
ƒ
ƒ
Can Connect with HYC9088 in Normal Mode
Can Connect with RS485 Transceiver,
HYC5000/4000/2000, Opt Module and TTL
Interface in Backplane Mode
Supports both Normal and Backplane Mode at
the Same Time for Media Conversion
+ 5V Single Power
GENERAL DESCRIPTION
When configuring a network, the maximum number of nodes and the maximum cable length are limited by the electric
capacity of the transceiver. In this case, the network is expanded by an equipment called a “HUB” or “repeater”. It
maybe necessary to have a converter between coax, T/P and the fiber cable. It is easy to design a HUB or a repeater
because the TMC2005 has various features for expanding such network.
It can connect with HYC9088, RS485 transceiver, HYC5000/4000/2000 and TTL interface for optical module. It can
connect with three different transceivers at the same time and convert the media of each. (The data rate cannot be
converted. It is necessary to operate all nodes in the same network at the same data rate). The Hubs can be
expanded by connecting two or more TMC2005 chips. By setting one of 5 ports to open-drain output, the Hub can be
expanded to either 12 or 16 ports.
ORDERING INFORMATION
Order Number(s):
TMC2005-JT for 64 pin TQFP package (green, lead-free)
SMSC TMC2005-JT
Revision 1.0 (01-30-06)
DATASHEET
ARCNET 5 Port HUB Controller
Datasheet
80 Arkay Drive
Hauppauge, NY 11788
(631) 435-6000
FAX (631) 273-3123
Copyright © 2006 SMSC or its subsidiaries. All rights reserved.
Circuit diagrams and other information relating to SMSC products are included as a means of illustrating typical applications. Consequently, complete
information sufficient for construction purposes is not necessarily given. Although the information has been checked and is believed to be accurate, no
responsibility is assumed for inaccuracies. SMSC reserves the right to make changes to specifications and product descriptions at any time without
notice. Contact your local SMSC sales office to obtain the latest specifications before placing your product order. The provision of this information
does not convey to the purchaser of the described semiconductor devices any licenses under any patent rights or other intellectual property rights of
SMSC or others. All sales are expressly conditional on your agreement to the terms and conditions of the most recently dated version of SMSC's
standard Terms of Sale Agreement dated before the date of your order (the "Terms of Sale Agreement"). The product may contain design defects or
errors known as anomalies which may cause the product's functions to deviate from published specifications. Anomaly sheets are available upon
request. SMSC products are not designed, intended, authorized or warranted for use in any life support or other application where product failure
could cause or contribute to personal injury or severe property damage. Any and all such uses without prior written approval of an Officer of SMSC
and further testing and/or modification will be fully at the risk of the customer. Copies of this document or other SMSC literature, as well as the Terms
of Sale Agreement, may be obtained by visiting SMSC’s website at http://www.smsc.com. SMSC is a registered trademark of Standard Microsystems
Corporation (“SMSC”). Product names and company names are the trademarks of their respective holders.
SMSC DISCLAIMS AND EXCLUDES ANY AND ALL WARRANTIES, INCLUDING WITHOUT LIMITATION ANY AND ALL IMPLIED WARRANTIES
OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, TITLE, AND AGAINST INFRINGEMENT AND THE LIKE, AND ANY AND
ALL WARRANTIES ARISING FROM ANY COURSE OF DEALING OR USAGE OF TRADE. IN NO EVENT SHALL SMSC BE LIABLE FOR ANY
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REVENUES OF ANY KIND; REGARDLESS OF THE FORM OF ACTION, WHETHER BASED ON CONTRACT; TORT; NEGLIGENCE OF SMSC
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HAVE FAILED OF ITS ESSENTIAL PURPOSE, AND WHETHER OR NOT SMSC HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
DAMAGES.
Revision 1.0 (01-30-06)
Page 2
DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
TABLE OF CONTENTS
FEATURES..................................................................................................................................................................1
GENERAL DESCRIPTION.......................................................................................................................................1
PIN CONFIGURATION ............................................................................................................................................4
BLOCK DIAGRAM....................................................................................................................................................4
BLOCK DIAGRAM....................................................................................................................................................5
DESCRIPTION OF PIN FUNCTIONS ....................................................................................................................5
DESCRIPTION OF PIN FUNCTIONS ....................................................................................................................6
TX/RX INTERFACE ....................................................................................................................................................7
OPERATING MODE SETUP ..........................................................................................................................................8
PLL ...........................................................................................................................................................................8
OTHER SIGNALS ........................................................................................................................................................9
OPERATIONAL DESCRIPTION...........................................................................................................................10
DIRECTION DETERMINATION ...................................................................................................................................10
DIRECTION RELEASE ...............................................................................................................................................10
JITTER FILTER ..........................................................................................................................................................10
OPTION FEATURE FOR JITTER FILTERING .................................................................................................................11
OPTION FEATURE FOR NOISE CUT MODE .................................................................................................................11
APPLICATION NOTES ........................................................................................................................................12
PORT GROUP...........................................................................................................................................................20
VARIOUS SETUP.......................................................................................................................................................20
EXAMPLE FOR OPERATION MODE SETUP TO EACH PORT........................................................................................20
NOTE FOR UNUSED PORT .........................................................................................................................................20
EXAMPLE FOR POWER-ON RESET CIRCUIT ..............................................................................................................20
CONNECTING THE TMC2005 WITH INTERNAL PLL...................................................................................21
METHOD TO CONNECT A CRYSTAL CLOCK .............................................................................................................22
NPLLTST PIN ..........................................................................................................................................................22
CASCADING CONNECTION ................................................................................................................................23
RING NETWORK WITH THE TMC2005.....................................................................................................................26
MAXIMUM GUARANTEED RATINGS*............................................................................................................27
STANDARD OPERATING CONDITION ............................................................................................................27
DC CHARACTERISTIC - INPUT PIN ..................................................................................................................27
DC CHARACTERISTIC - OUTPUT PIN ..............................................................................................................28
AC CHARACTERISTIC - CLOCK AND RESET...................................................................................................28
AC CHARACTERISTIC – RX WAVEFORMS AND TX WAVEFORMS ........................................................................29
TMC2005-JT 64 PIN TQFP PACKAGE OUTLINE .............................................................................................31
SMSC TMC2005-JT
Page 3
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
MB
RXINB1
LB
TXENB0
SB
RXINB0
VSS8
NC
VDD6
TXENA1
MA
RXINA1
LA
TXENA0
SA
RXINA0
PIN CONFIGURATION
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
16
17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
TMC2005-JT
VSS7
nPULSE1
nPULSE2
nP1BAK
VDD5
nCKOEN
nRST
VSS6
nBJA
nBJB
nBJE
nMBA
nMBB
nMBE
nEXTOD
NC
RXFLT
nPLLTST
VDD2
XTLI
XTLO
VSS4
NC
VDD4
VDD3
AVDD
R0
LP
AGS
AVSS
VSS3
VSS5
TXENB1
HM
SE
NC
LE
EXTRX
ME
VSS1
EXTTX
VDD1
CKO
VSS2
CKM2
CKM1
CKM0
NC
Revision 1.0 (01-30-06)
Page 4
DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
BLOCK DIAGRAM
nM B E nM B A
nB JB
nB JE
SE SB SA
R X IN A 0
R X IN A 1
NOT
Circuit
R X IN B 0
R X IN B 1
NOT
Circuit
EX TR X
nB JA
MB
ME
nM B B
LB
MA
Direction Control
Circuit
NOT
Circuit
LE
LA
nEX TO D
OR
Circuit
NOT
Circuit
TXEN A 0
TXEN A 1
OR
Circuit
NOT
Circuit
TXEN B 0
TXEN B 1
OR
Circuit
NOT
Circuit
HM
R X FLT
Output
Control
Circuit
Rx
Buffer
DPLL
Tx
Pulse
Gen.
EX TTX
nP 1B A K
nP U LSE1
nPU LS E2
V S S1-8
V D D 1-6
XTLO
XTLI
AVDD
A V SS
Clock Multiplier
PLL
AND
Circuit
C KO
nR S T
C KM 0
C KM 2
C K M 1 nPLLTST
SMSC TMC2005-JT
A VSS
RO
nC KO EN
LP
Page 5
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
DESCRIPTION OF PIN FUNCTIONS
PIN NO.
1
NAME
TXENB1
INPUT/OUTPUT
OUTPUT
2
HM
INPUT
3
4
SE
NC
INPUT
5
LE
INPUT
6
EXTRX
INPUT
7
8
9
10
11
12
13
14
15
16
17
ME
VSS1
EXTTX
VDD1
CKO
VSS2
CKM2
CKM1
CKM0
NC
RXFLT
INPUT
18
19
20
21
22
23
24
25
26
27
nPLLTST
VDD2
XTLI
XTLO
VSS4
NC
VDD4
VDD3
AVDD
RO
28
29
30
31
32
33
LP
AGS
AVSS
VSS3
VSS5
NC
34
35
36
37
nEXTOD
nMBE
nMBB
nMBA
INPUT
INPUT
INPUT
INPUT
38
nBJE
INPUT
39
nBJB
INPUT
40
41
42
43
nBJA
VSS6
nRST
nCKOEN
INPUT
Revision 1.0 (01-30-06)
OUTPUT
OUTPUT
INPUT
INPUT
INPUT
INPUT
INPUT
INPUT
OUTPUT
OUTPUT
OUTPUT
INPUT
INPUT
INPUT
DESCRIPTION
Port B-1 Tx output to media transceiver
Setting for traffic release time (It should
be open for normal operation.)
Port EXT. Polar assignment for EXTRX
input (0:active Hi, 1:active Low)
Reserved. It should be open.
Port EXT. Polar assignment of EXTTX
output (0:active Low, 1:active Hi)
Port EXT. RX-Data input from media
transceiver.
Port EXT. Output mode assignment of
EXTTX (0:pulse output, 1:Tx control
output)
Ground
Port EXT. Output to media transceiver.
Power Supply
Clock Output
Ground
Network speed (data rate) setting.
Reserved. It should be open.
Test Pin. It should be open.
Test Pin for PLL.. It should connected to
VDD (Set to high)
Power Supply
X'tal input/External clock input.
X'tal output
Ground
Reserved. It should be open.
Power Supply
Power Supply
Analog Power Supply
VCO output for internal PLL.
Connection pin to loop filter for internal
PLL.
Analog sense pin for internal PLL.
Analog Ground
Ground
Ground
Reserved. It should be open.
Port EXT. Open-drain mode (0:opendrain output, 1:normal output)
Port EXT. Noise cut (0:on, 1:off)
Port A0/A1 Noise cut (0:on, 1:off)
Port B0/B1 Noise cut (0:on, 1:off)
Port EXT. Jitters correct mode (0:big
jitters mode, 1:normal mode)
Port A0/A1 Jitters correct mode (0:big
jitter mode, 1:normal mode)
Port B0/B1 Jitter correct mode (0:big
jitter mode, 1:normal mode)
Ground
Internal reset signal (active Low)
Enable of CKO output.
Page 6
DATASHEET
NOTE
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
PIN NO.
44
45
46
47
48
NAME
VDD5
nP1BAK
nPULSE2
nPULSE1
VSS7
INPUT/OUTPUT
OUTPUT
OUTPUT
OUTPUT
49
RXINA0
INPUT
50
51
SA
TXENA0
INPUT
OUTPUT
52
LA
INPUT
53
RXINA1
INPUT
54
55
56
57
58
MA
TXENA1
VDD6
NC
VSS8
INPUT
OUTPUT
59
RXINB0
INPUT
60
61
SB
TXENB0
INPUT
OUTPUT
62
LB
INPUT
63
RXINB1
INPUT
64
MB
INPUT
Note:
DESCRIPTION
Power Supply.
nPULSE1 output (for backplane mode).
nPULSE2 output (for normal mode).
nPULSE1 output (for normal mode)
Ground
Port A-0 Rx-data input from media
transceiver.
Port A. Polar assignment for RXINA0/A1
output (0:active Hi, 1:active Low)
Port A-0 Tx output to media transceiver.
Port A. Polar assignment for TXENA0/A1
output (0:active Low, 1:active Hi)
Port A-1 Rx-data input from media
transceiver.
Port A. Mode assignment for
TXENA0/A1 (0:pulse output, 1:Tx control
output)
Port A-1 Tx output to media transceiver.
Power Supply
Reserved. It should be open.
Ground
Port B-0 Rx-data input from media
transceiver.
Port B. Polar assignment for RXINA0/A1
input (0:active Hi, 1:Active Low)
Port B-0 Tx output to media transceiver.
Port B. Polar assignment for TXENA0/A1
output (0:active Low, 1:active Hi)
Port B-1 Rx-data input from media
transceiver.
Port B. Mode assignment for
TXENA0/A1 (0:pulse output, 1:TX control
output)
NOTE
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up
Pull-up: Input with a pull-up resistor 70KΩ ± 30%
TX/RX Interface
FEATURE
RX Port
RX Port
Polar
Assignment
TX Port
TX Control
TX Port
TX Data
Output
TX Port
SMSC TMC2005-JT
NAME
RXINA [0:1]
RXINB [0:1]
EXTRX
SA, SB, SE
INPUT/OUTPUT
INPUT
DESCRIPTION
Setup the polarity by SA, SB, SE.
INPUT
Setup the polarity of RXINA [0:1],
RXINB [0:1], EXTTX.
0 : active H
1: active L
TX data pulse (Mx=0) or TX
enable signal (Mx=1).
Setup TX mode by MA, MB, ME.
Setup the polarity by LA, LB, LE
TX pulse data into HYC9068SSK/9088S-SK when ARCNET
chip is at normal mode.
The pulse is always active Low.
TX pulse data into RS485 driver
or HYC2485S/2488S when
ARCNET chip is at backplane
TXENA [0:1]
TXENB [0:1]
EXTTX
OUTPUT
nPULSE [1:2]
OUTPUT
nP1BAK
OUTPUT
Page 7
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
FEATURE
NAME
INPUT/OUTPUT
TX Port
Polarity
Setup
LA, LB, LE
INPUT
TX Port
Mode Setup
MA, MB, ME
INPUT
DESCRIPTION
mode.
The pulse is always active Low.
Setup the polarity of TXENA
[0:1], TXENB [0:1], EXTTX.
0 : active L
1: active H
Setup the mode of TXENA [0:1],
TXENB [0:1], EXTTX.
0: Output TX pulse. (It is
equivalent to nTXEN “OR”
nP1BAK)
1: Output TX enable
Operating Mode Setup
FEATURE
Data rate
setup
NAME
CKM [0:2]
INPUT/
OUTPUT
INPUT
DESCRIPTION
Terminal to setup the data rate of TMC2005.
CKM2 CKM1 CKM0 DIVISOR MULTIPLIER SPEED
0
0
0
16
x1
156.25 Kbps
0
0
1
8
x1
312.5 Kbps
0
1
0
4
x1
625 Kbps
0
1
1
2
x1
1.25 Mbps
1
0
0
1
x1
2.5 Mbps
1
0
1
1
x2
5 Mbps
1
1
0 Reserved Reserved
Reserved
1
1
1
1
x4
10 Mbps
External clock is 20MHz.
Refer to “VARIOUS SETUP”
Noise cut
mode
nMBA
nMBB
nMBE
INPUT
Big jitter
mode
nBJA
nBJB
nBJE
INPUT
nEXTOD
INPUT
Open drain
mode
0: Cut off noise from received data
1: Don’t cut off noise
Setup “0” normally.
Setup a jitter filter feature.
Select a pulse as reference phase used by DPLL.
0: 2nd pulse (big jitter mode)
1: 1st pulse (normal mode)
Setup a the use of EXTTX port.
0: Set EXTTX as open drain output and use as Ext.
1: Set EXTTX as normal output and use as 5th port.
PLL
FEATURE
NAME
LP
INPUT/
OUTPUT
OUTPUT
RO
OUTPUT
AGS
INPUT
DESCRIPTION
Using PLL: Connect to an external condenser
“C1” for loop filter.
Using no PLL: must be open.
VCO output
Using PLL: Connect to an external resistor “R0” for
loop filter.
Using no PLL: must be open.
Analog sense input.
Using PLL: Connect to loop filter.
Using no PLL: Connect to ground.
Revision 1.0 (01-30-06)
Page 8
DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
FEATURE
NAME
nPLLTST
INPUT/
OUTPUT
INPUT
AVDD
DESCRIPTION
Test pin for PLL.
Must always connect to VDD.
Analog power supply
AVSS
Using PLL: Analog power supply. There are some
limits on PCB pattern.
Using no PLL: Power supply (+5V) same as VDD1~6.
Analog ground
Using PLL: Analog ground. There are some limits on
PCB pattern.
Using no PLL: Use a ground same as VSS1~8.
Other Signals
FEATURES
CRYSTAL
INTERFACE
INPUT/
OUTPUT
INPUT
NAME
XTLI
CRYSTAL
INTERFACE
XTLO
OUTPUT
SYSTEM RESET
INTERFACE
TEST PIN
TEST PIN
nRST
INPUT
CKO
nCKOEN
OUTPUT
INPUT
TEST PIN
TEST PIN
POWER SUPPLY
GROUND
RXFLT
NC [1:2]
VDD [1:6]
VSS [1:8]
INPUT
SMSC TMC2005-JT
DESCRIPTION
Connect a 20MHz crystal.
When supplying an external clock,
input the clock to this pin.
Connect a 20MHz crystal.
When supplying an external clock, it
must be open.
Reset for initializing TMC2005. (active
Low)
Output internal clock of TMC2005.
Output control of CKO.
0: Output internal clock on CKO.
1: Always output Low level on CKO.
Set “1” Normally.
It must be open
It must be open
Power supply (+5V)
Ground
Page 9
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
OPERATIONAL DESCRIPTION
Direction Determination
All TX ports are set to disable mode in the initial state. When a signal is received from any RX ports, the circuit holds
the port on receiving mode (disable TX) and changes the other ports to sending mode (disable RX). One port stays in
RX and the rest change into TX after all. The circuit initializes the internal DPLL on the timing of received RX pulse,
and the RX buffer circuit stores the RX data and filters its jitter. TX controlling circuit regenerates the stored RX pulse
on nPULSE1, nPULSE2 and nP1BAK. The nPULSE1 and nPULSE2 are pulse output pins for transceivers
(HYC9088A) of ARCNET normal mode. The nP1BAK is a pulse output pin for transceiver (HYC5000/4000/2000 and
RS485 driver) of ARCNET back plane mode. When using optical transceiver, instead of these signals, TXENA [0:1],
TXENB [0:1], EXTTX (MA, MB, ME = 0) must be used as TX data inputs of the optical transceiver.
Direction Release
On ARCNET protocol, each TX message starts with 6-bits of “1” ALERT and each data byte is lead by three bits (1, 1,
0) preamble. To control the HUBs direction, the circuit monitors this bit pattern and holds the state. If the end of the bit
pattern comes, all TX ports return receiving mode (disable TX) again. The interval timer detects the end of the bit
pattern. During data is on line, silent period is less than 4 uS* because at least one bit “1” among 10-bits is received
while receiving the data. The minimum silent interval from the end of received data to the alert of the next data (the
minimum time of changing the direction) is the chip turn around time (12.6 uS*) of ARCNET controller. The interval
timer to detect the data end is set to 5.6uS by adding some margin to the above interval for neglecting the reflection
on a cable.
[Note] Numbers marked * are at 2.5Mbps operation.
Jitter Filter
To build a network with transceivers that introduce big jitter like ones for optical fiber, the old HUB that has direction
control only may cause a transmission error because jitters on each HUB are added when several HUBs were
connected in serial. The TMC2005 fixes that problem with jitter filtering and wave shaping through the following three
steps.
1) Input Sampling
The TMC2005 samples a data on a network by eight times clock of the network data.
2) Jitter Filtering (DPLL)
The TMC2005 filters the jitter (± 100nS at 2.5Mbps) of network data sampled by 8X clock through the internal digital
PLL and stores the data into the buffer.
3) Wave Shaping Output
The TMC2005 re-synchronizes and regenerates the network data at the same clock as the data rate.
The capability of the jitter filtering is shown below.
DATA RATE
10Mbps
5Mbps
2.5Mbps
1.25Mbps
625Kbps
312.5Kbps
156.25Kbps
Revision 1.0 (01-30-06)
CAPABILITY OF JITTER FILTERING
± 25nS
± 50nS
± 100nS
± 200nS
± 400nS
± 800nS
± 1.6uS
Page 10
DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
Option Feature for Jitter Filtering
When any RX ports receive the bigger jitter than its allowance, the TMC2005 may fail to receive the data
correctly and the network may be down.. However the below method to escape is effective for the case that a
momentary big jitter occurs under a special condition like an optical transceiver.
1) Big jitter (BJ) mode
The reference phase of the internal DPLL is changed from the first pulse to the second pulse by setting “0” to the big
jitter mode pins (nBJX). This setup is effective for the case that a big jitter occurs when rising up from DC state as
same as when using an optical transceiver with ATC function (refer to complement).
Note: The delay time of the TMC2005 becomes 400nS (at 2.5Mbps) longer than the normal mode. The delay time
limits the maximum cable length and maximum node number.
[Complement] The big jitter may occur in the case of using an optical transceiver, especially an optical receiver that
has an ATC circuit that controls threshold level in proportion to received light strength. The first pulse especially after
long time idle has the big jitter but the second pulse is stabilized.
2) Changing polar of RX port
In order to filter the jitter of edge in one side, it is effective to set reverse to pin SA, SB, SE to change the polarity of
RX port.
Note: Changing the polarity of RX port makes the delay time of the TMC2005 circuit a half bit (200nS) longer than
original 2.5Mbps, and the delay time affects the maximum cable length and maximum node number.
Option Feature for Noise Cut mode
The Noise cut mode is enabled by setting pin nMBx sets 0. The noise cut mode is a function to remove the ringing
noise and the reflection noise generated on the leading edge side of the input pulse to receive data input RXINx. The
position and the width of the “dead band” are shown in the figure below.
- Dead band at Normal mode (nMBx=1)
- Dead band at Noise cut mode (nMBx=0)
Period of data rate (Tdr)
Period of data rate (Tdr)
Tdr/8 = 1 clock
Tdr/8 = 1 clock
RXIN
(Active High)
RXIN
(Active High)
Ideal waveform
Ideal waveform
dead band: Noise cut band
dead band
RXIN edge reference position:
Generated by adjacent phase of SYNC character (1,1,0)
SMSC TMC2005-JT
RXIN edge reference position:
Generated by adjacent phase of SYNC character (1,1,0)
Page 11
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
APPLICATION NOTES
Example 1: A five ports HUB with HYC4000s in backplane mode.
FIGURE 1 - APPLICATION EXAMPLE
Only the TMC2005 and five transceivers are indicated in the above figure. Connect the other pins adequately.
Revision 1.0 (01-30-06)
Page 12
DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
Example 2: A five ports HUB with HYC9088s and a optical transceiver(TODX270A) links the two physical layers;
dipulse and fiber optics.
FIGURE 2 - APPLICATION EXAMPLE 2
Only the TMC2005 and five transceivers are indicated in the above figure. Connect the other pins adequately.
SMSC TMC2005-JT
Page 13
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
Example 3: A five ports HUB with two optical transceivers, two HYC9088s, and a HYC4000 links three physical
layers; fiber optics, dipulse, and AC-485.
FIGURE 3 - APPLICATION EXAMPLE 3
Only the TMC2005 and five transceivers are indicated in the figure above. Connect the other pins properly.
Revision 1.0 (01-30-06)
Page 14
DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
Example 4: An on-board type HUB with a COM20020 and four optical transceivers in backplane mode.
FIGURE 4 - APPLICATION EXAMPLE 4
Only the TMC2005 and four transceivers with the COM20020 are indicated in the above figure. Connect the other
pins adequately.
SMSC TMC2005-JT
Page 15
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
Example 5: An on-board type HUB with a COM20020 and four RS485 transceivers.
FIGURE 5 - APPLICATION EXAMPLE 5
Only the TMC2005 and four transceivers with the COM20020 are indicated in the above figure. Connect the other
pins adequately.
Revision 1.0 (01-30-06)
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DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
Example 6: An on-board type HUB with a COM20020, two HYC4000s, and two HYC9088s links two different physical
layers; dipulse and AC-485.
FIGURE 6 - APPLICATION EXAMPLE 6
Only the TMC2005 and four transceivers with the COM20020 are indicated in the above figure. Connect the other
pins adequately.
SMSC TMC2005-JT
Page 17
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
Example 7: An eight ports HUB are composed by using two TMC2005. Two TMC2005 connects the EXTTX signal
with the EXTRX signal.
FIGURE 7 - APPLICATION EXAMPLE 7
Only the two TMC2005s are indicated in the above figure. Connect the other pins adequately.
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DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
Example 8: A sixteen ports HUB are composed by using four TMC2005. The EXT port between TMC2005 is made an
open-drain mode and it connects it (left example). Or put standard logic IC such as 74LS22 outside (right example).
This connected method is excellent in noised respect compared with connected method of open-drain mode.
Data rate: 5Mbps and below
Data rate: 10Mbps and below
or
FIGURE 8 - APPLICATION EXAMPLE 8
Only the four TMC2005s are indicated in the above figure. Connect the other pins adequately.
Note: Use the wiring pattern length that connects between four TMC2005s by five inches or less in open-drain mode.
Four TMC2005s is maximum in open-drain mode.
SMSC TMC2005-JT
Page 19
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
PORT GROUP
The five ports can be divided into three groups (group A: two ports, group B: two ports, extension port: one port) and
each group can select TX/RX polar, noise cut mode, and big jitter mode respectively. Select pins for each group are
as follows:
FUNCTION
RECEIVE
TRANSMIT
RX POLARITY
TX POLARITY
TX CONTROL
NOISE CUT
BIG JITTER
EXTENSION
GROUP A
RXINA0, 1
TXENA0, 1
SA
LA
MA
nMBA
nBJA
GROUP B
RXINB0, 1
TXENB0, 1
SB
LB
MB
nMBB
nBJB
EXTENSION
EXTRX
EXTTX
SE
LE
ME
nMBE
nBJE
nEXTOD
Various Setup
SA, SB, SE
1
0
0
1
Example For Operation Mode Setup To Each Port
LA, LB, LE
MA, MB, ME
RX POLAR
TX POLAR
TRANSCEIVER
0
1
Active Low
Active Low
HYC2485S/HYC2488S
1
0
Active High
Active High
Optical Transceiver
0
1
Active High
Active Low
HYC9088/HYC9068
1
1
Active Low
Active High
RS485 Transceiver
Note for Unused port
Unused ports can be left open because RX port (RX input), RX polar (S input), TX polar (L input), TX control (M input)
pins have internal pull-up resistors. Because of internal pull-up resistors, select pins for noise cut (nMB input), big
jitter (nBJ input) can be left open when used for setting “OFF”.
Example for Power-On Reset Circuit
FIGURE 9 - POWER-ON RESET
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DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
CONNECTING THE TMC2005 WITH INTERNAL PLL
When using the TMC2005 at data rate 2.5Mbps or lower, it is not necessary to use internal PLL. Leave the loop filter
pins (RO, LP) open and connect AGS to the Ground. The pins for the analog power supply (AVSS, AVDD) may
connect to digital power supply. When using the TMC2005 at data rate 5Mbps or higher, the internal PLL has to be
used as a clock multiplier. PCB layout must follow the guidelines at Figure 10, refer to Notes 1 through 5.
FIGURE 10 - PLL PATTERN LAYOUT
Note 1: Prohibit the patterns for LP and RO from occupying the area of digital power supply. Use the area of analog
power supply between VAA and AVSS.
Note 2: Encircle the pattern between LP, RO and AGS with wide pattern of analog ground.
Note 3: Connect the analog power supply “VAA” with 0.1 uF condenser (a) with in 1/8 inch (~ 3.2mm) from VAA pin.
Note 4: In order to filter the jitter of low frequency, connect a 10 uF condenser (b) in parallel with the condenser (a).
Note 5: Place 0.1 uF bypass condenser (c) within ¼ inch (~ 6.4mm) from VDD3 and VSS3. Connect the ground side
of a condenser (c) at the place (*) where AVSS returns to GND plane.
SMSC TMC2005-JT
Page 21
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
Method To Connect A Crystal Clock
Connect with external parts as follows:
FIGURE 11 - CONNECTING THE CRYSTAL CLOCK
Note 1: When designing a printed circuit board, keep the patterns as short as possible and don’t cross with other
patterns.
Note 2: When using an external clock like an oscillator module, connect it to XTLI pin and leave XTLO pin open.
When designing a printed circuit board, wire between XTLI pin and oscillator should be short as possible.
nPLLTST pin
nPLLTST must be connect toVDD. The rest of input pins have pull-up resistors built in, but nPLLTST pin does not
have the pull-up resistor. Clock signal cannot ditributed into the TMC2005 if nPLLTST pin is connected GND or is left
open.
Revision 1.0 (01-30-06)
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DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
CASCADING CONNECTION
HUBs can be connected in cascade by using the ports as Fig. 12. In the case of cascade connection, it is necessary
to consider how many HUBs can exist in serial. The maximum delay between input port and output port is 650ns
@2.5Mbps at the TMC2005. It is equivalent to the propagation delay when a cable length is 135m. For example, if
every cable length is 10m in Figure 12, the longest distance is physically 50m but it is electrically 590m because of
multiplying 10m by 5 and 135m by 4, and the total propagation delay becomes 2.8uS. For analyzing the network
timing, consider the delay caused by HUBs. In the ARCNET protocol, it is defined that the longest distance between
nodes is the maximum 6.4Km. For example, if 20 TMC2005s exist between nodes in the longest distance, the actual
cable length is 3.7Km because of deducting 135m by 20 in converting to cable length from 6.4Km.
NODE
Port 1
Port 2
Port 3
Port 4
Port 5
TMC2005
1
2
3
4
5
Port 1
Port 2
Port 3
Port 4
Port 5
TMC2005
1
2
3
4
5
Port 1
Port 2
Port 3
Port 4
Port 5
TMC2005
1
2
3
4
5
1
2
3
4
5
Port 1
Port 2
Port 3
Port 4
Port 5
TMC2005
NODE
FIGURE 12 - CASCADE CONNECTION OF 4 HUBS
Two examples of eight ports HUBs using two TMC2005s are shown in Fig. 13 and 14. If connecting as in Fig. 13,
eight TMC2005s exist between the nodes at both far ends. On the other hand, when assigning two ports for
cascading connection to the same TMC2005, the number of TMC2005 in serial connection can be down to the
number of HUBs plus two, which can reduce the propagation delay.
SMSC TMC2005-JT
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DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
TMC2005
2
3
4
5
1
2
3
4
TMC2005
1
2
3
4
2
3
4
5
2
3
4
5
2
3
4
5
1
2
3
4
TMC2005
1
2
3
4
TMC2005
2
3
4
5
TMC2005
HUB4
2
3
4
5
HUB 3
1
2
3
4
TMC2005
2
3
4
5
TMC2005
2
3
4
5
1
2
3
4
1
2
3
4
TMC2005
HUB2
1
2
3
4
HUB 1
NODE
NODE
FIGURE 13 - CASCADE CONNECTION OF 8 PORT HUB
NODE
TMC2005
2
3
4
5
1
2
3
4
TMC2005
1
2
3
4
2
3
4
5
TMC2005
1
2
3
4
2
3
4
5
TMC2005
2
3
4
5
TMC2005
HUB4
2
3
4
5
HUB 3
1
2
3
4
1
2
3
4
1
2
3
4
TMC2005
2
3
4
5
TMC2005
2
3
4
5
1
2
3
4
1
2
3
4
TMC2005
HUB2
2
3
4
5
HUB 1
NODE
FIGURE 14 - CASCADE CONNECTION OF 8 PORT HUB
Revision 1.0 (01-30-06)
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DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
Fig.15 shows a 16 ports HUB with four TMC2005s connected by open–drain ports. When assigning two ports for
cascade connection to the same TMC2005, the number of TMC2005s for serial connection can be reduced to the
number of HUBs plus two.
1
2
3
4
TMC2005
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
1
2
3
4
TMC2005
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
1
2
3
4
TMC2005
HUB 3
1
2
3
4
HUB2
NODE
TMC2005
1
2
3
4
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
1
2
3
4
TMC2005
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
TMC2005
1
2
3
4
1
2
3
4
1
2
3
4
TMC2005
HUB 4
1
2
3
4
HUB 1
NODE
FIGURE 15 - CASCADE CONNECTION OF 16 PORT HUB
Note:
When connecting TMC2005 by open-drain output on a board, connecting TMC2005s must be four or less,
and the data rate must be 5Mbps or slower. The pattern of open-drain output has to be as short as possible
(less than 15cm).
SMSC TMC2005-JT
Page 25
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
Ring Network With the TMC2005
The reliability of the network can be improved by connecting every node in a ring, because the communication is
maintained through the reverse route even if the cable is cut at a point. However ARCNET controller alone can not
support ring, because ARCNET is a half-duplex communication system. Using HUBs makes possible for ARCNET to
built a ring network as in Fig.16. This configuration is available only for using fiber optics. (Refer to the application note
for details.)
Optical Transceiver
COM20020
TMC2005
A
B
Optical Fiber
COM20020
TMC2005
TMC2005
COM20020
nRST
TXEN
nRESET
CK
CT
TMC2005
TXEN of any port
COM20020
FIGURE 16 - RING CONFIGURATION
Note 1: Noise may cause an endless loop in a ring system, and the network may hang up. Therefore take care of
designing the patterns between TMC2005 and transceiver or cabling of system.
Example for system hang-up
A noise occurs only at “A” point in Figure 16.
The noise propagates clockwise on the network.
TMC2005 detects the noise that came back through the ring.
The noise causes an endless loop in the ring.
Example for no hang-up
Any noise occurs at “A” and “B” points in Figure 16 at the same time.
The noise propagates to both directions in the network.
An endless loop doesn’t occur because TMC2005s in the middle absorb the noise from both sides.
Note 2: Place a watch dog timer on one of the TMC2005 in at least one ring. To protect from hang-up the detecting
time of the watch dog timer should be set to longer than 2.7 mS (@ 2.5Mbps) that is the burst time in the
ARCNET protocol.
Note 3: Consider that a total of each segment delay time (cable delay, TMC2005 delay, driver delay and receiver
delay) between HUBs in a network is less than 5.6uS (@ 2.5Mbps). The maxmimum distance between
HUBs is approximiately 1000m (@ 2.5Mbps).
Revision 1.0 (01-30-06)
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DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
OPERATIONAL DESCRIPTION
MAXIMUM GUARANTEED RATINGS*
Stresses above those listed may cause permanent damage to the device. This is a stress rating only and functional
operation of the device at these or any other condition above those indicated in the operational sections of this
specification is not implied.
(Note) When powering this device from laboratory or system power supplies, it is important that the Absolute
Maximum Ratings not be exceeded or device failure can result. Some power supplies exhibit voltage spikes or
“glitches” on their output when the AC power is switch on or off. In addition, voltage transients on the AC power line
may appear on the DC output. If this possibility exists it is suggested that a clamp circuit be used.
Vss = 0V
ITEM
POWER SUPPLY VOLTAGE
INPUT VOLTAGE
OUTPUT VOLTAGE
AMBIENT TEMPERATURE
STANDARD OPERATING CONDITION
Vss = 0V
ITEM
POWER SUPPLY VOLTAGE
AMBIENT TEMPERATURE
SYMBOL
VDD
VIN
VOUT
Tstg
RATING
-0.3 +7.0
-0.3 VDD +0.3
-0.3 VDD +0.3
-40 +125
UNIT
V
V
V
°C
SYMBOL
VDD
Ta
RATING
4.5 – 5.5
0 - +85
UNIT
V
°C
DC CHARACTERISTIC - INPUT PIN
SYMBOL
ITEM
VIH
High Level Input Voltage
VIL
IIH
IIL
IIL
IOZ
IDD
Low Level Input Voltage
High Level Input Current
Low Level Input Current
With pull-up
Output Leak Current
Dissipation Current
SMSC TMC2005-JT
CONDITION
XTLI, nPLLTST
Others
MIN
3.5
2.2
VIN=VDD
VIN=VSS
Vin=VSS
VOUT=VDD or VSS
Operating
-10
-10
-200
-10
Page 27
DATASHEET
MAX
0.8
10
10
-10
10
100
UNIT
V
V
V
uA
uA
uA
uA
mA
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
DC CHARACTERISTIC - OUTPUT PIN
SYMBOL
ITEM
VOH
High Level Output Voltage
CONDITION
IOH=-4mA
MIN
2.4
2.4
VOH
VOL
High Level Output Voltage
Low Level Output Voltage
IOH=-8mA
IOL=4mA
VOL
Low Level Output Voltage
IOL=8mA
AC CHARACTERISTIC - CLOCK and RESET
ITEM
SYMBOL
Generating Static Time
tx
Clock Cycle
tCYC
Clock Frequency Deflection
tCDF
Clock Pulse Width
tCW
Reset Pulse Width
ttRSW
MIN
MAX
TYP
0.4
V
V
0.4
V
MAX
4
UNIT
mS
nS
ppm
nS
nS
50
-100
20
200
UNIT
V
100
PIN
1,9,46,51,
55,61
11,45,47
1,9,46,51,
55,61
11,45,47
CONDITION
Note 1
Note 1
Note 1
Note 1
Note 1: Use only F=20MHz
Note 2: VDD=4.5V
XTLI
t CW
t CW
tCYC
nRST
t RSW
FIGURE 17 - CLOCK AND RESET
Revision 1.0 (01-30-06)
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DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
AC CHARACTERISTIC – Rx waveforms and Tx waveforms
t2
t1
RXINx (S=1)
(Received port)
t3
t4
t5
TXENy (M=1, L=0)
* 4 ports except received port
t6
t8
t7
nP1BAK
/TXENy (M=0, L=0)
t10
t9
* 4 ports except received port
t11
t12
t13
t15
nPULSE1
t14
t16
t17
t18
nPULSE2
t19
FIGURE 18 - RX WAVEFORMS AND TX WAVEFORMS
ITEMS
MARK
MIN
TYP
MAX
RXIN Low Pulse Width
t1
15
nS
RXIN High Pulse Width
t2
15
nS
RXIN Period
t3
Tdr
UNIT
REMARK
nS
(Value at 2.5Mbps)
nS
Note1
(Value at 2.5Mbps)
nS
Note1
(Value at 2.5Mbps)
nS
Note2, Note3
(Value at 2.5Mbps)
nS
Note2
(Value at 2.5Mbps)
nS
Note2
(Value at 2.5Mbps)
nS
Note2
(Value at 2.5Mbps)
nS
Note2, Note3
(Value at 2.5Mbps)
(400)
RXIN First Active Edge to TXEN Active
RXIN Last Active Edge to TXEN Inactive
t4
t5
RXIN First Active Edge to
nP1BAK/TXEN First Active Edge
t6
nP1BAK/TXEN Low Pulse Width
t7
2/8Tdr
3/8Tdr+50
(100)
(200)
111/8Tdr
112/8Tdr+50
(5,550)
(5,650)
9/8Tdr
10/8Tdr+50
(450)
(550)
1/2Tdr
(200)
nP1BAK/TXEN High Pulse Width
1/2Tdr
t8
(200)
nP1BAK/TXEN Period
Tdr
t9
(400)
RXIN Active Edge to
nP1BAK/TXEN Active Edge
(Except First Edge of RXIN)
SMSC TMC2005-JT
t10
5/8Tdr
9/8Tdr+50
14/8Tdr+50
(250)
(500)
(750)
Page 29
DATASHEET
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
ITEMS
MARK
RXIN First Active Edge
to nPULSE1 First Active Edge
t11
nPULSE1 Low Pulse Width
t12
MIN
TYP
MAX
9/8Tdr
10/8Tdr+50
(450)
(550)
1/4Tdr
UNIT
REMARK
nS
Note3
(Value at 2.5Mbps)
nS
(Value at 2.5Mbps)
nS
(Value at 2.5Mbps)
nS
(Value at 2.5Mbps)
nS
Note3
(Value at 2.5Mbps)
(100)
nPULSE1 High Pulse Width
3/4Tdr
t13
(300)
nPULSE1 Period
Tdr
t14
(400)
RXIN Active Edge to
nPULSE1 Active Edge
(Except First Edge of RXIN)
t15
nPULSE1 to nPULSE2 Overlap
t16
nPULSE2 Low Pulse Width
t17
5/8Tdr
9/8Tdr+50
14/8Tdr+50
(250)
(500)
(750)
-10
0
+10
1/4Tdr
nS
nS
(Value at 2.5Mbps)
nS
(Value at 2.5Mbps)
nS
(Value at 2.5Mbps)
(100)
nPULSE2 High Pulse Width
3/4Tdr
t18
(300)
nPULSE2 Period
Tdr
t19
(400)
Tdr: Period of data rate, ex) Tdr=400nS at 2.5Mbps
Note1: Applied to TXENx which is set to Mx=1. (Tx Control mode)
Note2: Applied to TXENx which is set to Mx=0. (Pulse output mode)
Note3: Extra one “Tdr” time to be added at RXINx is set to nBJx=0. (Big Jitter mode)
Revision 1.0 (01-30-06)
Page 30
DATASHEET
SMSC TMC2005-JT
ARCNET 5 Port HUB Controller
Datasheet
TMC2005-JT 64 PIN TQFP PACKAGE OUTLINE
D
D1
Ze
E1
E
64
1
Zd
SYMBOL
D
D1
E
E1
Ze
Zd
SMSC TMC2005-JT
MIN (mm)
11.8
9.9
11.8
9.9
TYP (mm)
12.0
10.0
12.0
10.0
1.25 typ
1.25 typ
Page 31
DATASHEET
MAX (mm)
12.2
10.1
12.2
10.1
Revision 1.0 (01-30-06)
ARCNET 5 Port HUB Controller
Datasheet
A2
A
b
SYMBOL
A
A1
A2
B
E
aaa
bbb
c
SYMBOL
c
L
Revision 1.0 (01-30-06)
e
bbb M
aaa
MIN (mm)
TYP (mm)
0.95
1.35
0.17
0.1
1.4
0.22
0.5 BSC
0.08
0.08
A1
MAX (mm)
1.6
0.15
1.45
0.27
L
MIN (mm)
0.9
0.45
TYP (mm)
0.145
0.6
Page 32
DATASHEET
MAX (mm)
0.2
0.75
SMSC TMC2005-JT