ON CM2030-A0TR Hdmi receiver port protection and interface device Datasheet

HDMI Receiver Port Protection
and Interface Device
CM2030
Features
Product Description
•
•
•
•
The CM2030 HDMI Transmitter Port Protection and
Interface Device is specifically designed for next
generation HDMI Host interface protection.
•
•
•
•
•
•
•
•
HDMI 1.3 compliant
Supports thin dielectric and 2-layer boards
Minimizes TMDS skew with 0.05pF matching
2
Long HDMI cable support with integrated I C
accelerator
Active termination and slew rate limiting for CEC
Supports direct connection to CEC
microcontroller
2
Integrated I C level shifting to CMOS level including low logic level voltages
Integrated 8kV ESD protection and backdrive
protection on all external I/O lines
Integrated overcurrent output protection per
HDMI 1.3
2
Multiport I C support eliminates need for analog
mux on DDC lines
Simplified layout with matched 0.5mm trace
spacing
RoHS-compliant, lead-free packaging
An integrated package provides all ESD, slew rate
limiting on CEC line, level shifting/isolation,
overcurrent output protection and backdrive
protection for an HDMI port in a single 38-pin TSSOP
package.
The CM2030 part is specifically designed to provide
the designer with the most reliable path to HDMI 1.3
CTS compliance.
The CM2030 also incorporates a silicon overcurrent
protection device for +5V supply voltage output to the
connector.
Applications
•
•
PC and consumer electronics
Set top box, DVD RW, PC, graphics cards
©2010 SCILLC. All rights reserved.
May 2010 – Rev. 5
Publication Order Number:
CM2030/D
CM2030
Electrical Schematic
5V_SUPPLY
TMDS_D2+
TMDS_D1+
TMDS_D0+
TMDS_CK+
TMDS_GND
TMDS_GND
TMDS_GND
TMDS_GND
TMDS_D2-
TMDS_D1-
TMDS_D0-
TMDS_CK-
5V_SUPPLY
LV_SUPPLY
DDC_CLK_IN
5V_SUPPLY
LV_SUPPLY
DYNAMIC
PULLUP
CMOS/I2C
LEVEL SHIFT
DDC_DAT_IN
DYNAMIC
PULLUP
CMOS/I2C
LEVEL SHIFT
DDC_CLK_OUT
DDC_DAT_OUT
CE_SUPPLY
LV_SUPPLY
CE_SUPPLY
ACTIVE SLEW
RATE
LIMITING
IS
HOTPLUG_DET_IN
HOTPLUG_DET_OUT
CE_REMOTE_IN
3IS
55mA
OVERCURRENT
SWITCH
5V_SUPPLY
5V_OUT
PACKAGE / PINOUT DIAGRAM
TOP VIEW
Note: This drawing is not to scale.
5V_SUPPLY
1
38
5V_OUT
LV _SUPPLY
2
37
CE_SUPPLY
GND
3
36
GND
TMDS_D2+
4
35
TMDS_D2+
TMDS_GND
5
34
TMDS_GND
TMDS_D2–
6
33
TMDS_D2–
TMDS_D1+
7
32
TMDS_D1+
TMDS_GND
8
31
TMDS_GND
TMDS_D1–
9
30
TMDS_D1–
TMDS_D0+
10
29
TMDS_D0+
TMDS_GND
11
28
TMDS_GND
TMDS_D0–
12
27
TMDS_D0–
TMDS_CK+
13
26
TMDS_CK+
TMDS_GND
25
TMDS_GND
TMDS_CK–
14
15
24
TMDS_CK–
CE_REMO TE_IN
16
23
CE_REMO TE_OUT
DDC_CLK_IN
17
22
DDC_CLK_OUT
DDC_DAT _IN
18
21
DDC_DAT _OUT
HOT PLUG_DET_IN
19
20
HOT PLUG_DET_OUT
38-PIN TSSOP PACKAGE
Rev. 5 | Page 2 of 17 | www.onsemi.com
CE_REMOTE_OUT
CM2030
PIN DESCRIPTIONS
PINS
NAME
ESD Level
DESCRIPTION
4, 35
TMDS_D2+
8kV
3
TMDS 0.9pF ESD protection.
1
6, 33
TMDS_D2–
8kV
3
TMDS 0.9pF ESD protection.
1
TMDS 0.9pF ESD protection.
1
7, 32
TMDS_D1+
8kV
3
9, 30
TMDS_D1–
8kV
3
TMDS 0.9pF ESD protection.
1
10, 29
TMDS_D0+
8kV
3
TMDS 0.9pF ESD protection.
1
TMDS 0.9pF ESD protection.
1
12, 27
TMDS_D0–
8kV
3
13, 26
TMDS_CK+
8kV
3
TMDS 0.9pF ESD protection.
1
15, 24
TMDS_CK–
8kV
3
TMDS 0.9pF ESD protection.
1
CE_SUPPLY referenced logic level in.
16
CE_REMOTE_IN
2kV
4
23
CE_REMOTE_OUT
8kV
3
5V_SUPPLY referenced logic level out plus 10pF ESD.
17
DDC_CLK_IN
2kV
4
LV_SUPPLY referenced logic level in.
5V_SUPPLY referenced logic level out plus 10pF ESD.
22
DDC_CLK_OUT
8kV
3
18
DDC_DAT_IN
2kV
4
LV_SUPPLY referenced logic level in.
5V_SUPPLY referenced logic level out plus 10pF ESD.
6
6
21
DDC_DAT_OUT
8kV
3
19
HOTPLUG_DET_IN
2kV
4
LV_SUPPLY referenced logic level in.
HOTPLUG_DET_OUT 8kV
3
5V_SUPPLY referenced logic level out plus 10pF ESD. A 0.1µF
20
bypass ceramic capacitor is recommended on this pin.
6
2
2
LV_SUPPLY
2kV
4
37
CE_SUPPLY
2kV
4,2
CEC bias voltage. Previously CM2020 ESD_BYP pin.
2kV
4
Current source for 5V_OUT, VREF for DDC I C voltage references,
3
1
5V_SUPPLY
Bias for CE / DDC / HOTPLUG level shifters.
2
and bias for 8kV ESD pins.
38
5V_OUT
8kV
3, 5, 8, 11,
GND / TMDS_GND
N/A
55mA minimum overcurrent protected 5V output. This output must be
bypassed with a 0.1µF ceramic capacitor.
GND reference.
14, 25,
28, 31, 34, 36
Note 1: These 2 pins need to be connected together in-line on the PCB. See recommended layout diagram.
Note 2: This output can be connected to an external 0.1µF ceramic capacitor/pads to maintain backward compatibility with the
CM2020.
Note 3: Standard IEC 61000-4-2, CDISCHARGE=150pF, RDISCHARGE=330Ω, 5V_SUPPLY and LV_SUPPLY within recommended
operating conditions, GND=0V, 5V_OUT (pin 38), and HOTPLUG_DET_OUT (pin 20) each bypassed with a 0.1µF
ceramic capacitor connected to GND.
Note 4: Human Body Model per MIL-STD-883, Method 3015, CDISCHARGE=100pF, RDISCHARGE=1.5kΩ, 5V_SUPPLYand LV_SUPPLY
within recommended operating conditions, GND=0V, 5V_OUT (pin 38), and HOTPLUG_DET_OUT (pin 20) each
bypassed with a 0.1µF ceramic capacitor connected to GND.
Note 5: These pins should be routed directly to the associated GND pins on the HDMI connector with single point ground vias at
the connector.
Note 6: The slew-rate control and active acceleration circuitry dynamically offsets the system capacitive load on these pins.
Rev. 5 | Page 3 of 17 | www.onsemi.com
CM2030
Backdrive Protection and Isolation
Backdrive current is defined as the undesirable current flow through an I/O pin when that I/O pin’s voltage
exceeds the related local supply voltage for that circuitry. This is a potentially common occurrence in multimedia
entertainment systems with multiple components and several power plane domains in each system.
For example, if a DVD player is switched off and an HDMI connected TV is powered on, there is a possibility of
reverse current flow back into the main power supply rail of the DVD player from pull-ups in the TV. As little as a
few milliamps of backdrive current flowing back into the power rail can charge the DVD player’s bulk bypass
capacitance on the power rail to some intermediate level. If this level rises above the power-on-reset (POR)
voltage level of some of the integrated circuits in the DVD player, then these devices may not reset properly
when the DVD player is turned back on.
If any SOC devices are incorporated in the design which have built-in level shifter and/or ESD protection
structures, there can be a risk of permanent damage due to backdrive. In this case, backdrive current can
forward bias the on-chip ESD protection structure. If the current flow is high enough, even as little as a few
milliamps, it could destroy one of the SOC chip’s internal DRC diodes, as they are not designed for passing DC.
To avoid either of these situations, the CM2030 was designed to block backdrive current, guaranteeing less
than 5µA into any I/O pin when the I/O pin voltage exceeds its related operating CM2030 supply voltage.
Figure 1. Backdrive Protection Diagram.
Display Data Channel (DDC) lines
2
The DDC interface is based on the I C serial bus protocol for EDID configuration.
DYNAMIC PULLUPS
Based on the HDMI specification, the maximum capacitance of the DDC line can approach 800pF (50pF from
source, 50pF from sink, and 700pF from cable). At the upper range of capacitance values (i.e. long cables), it
2
becomes impossible for the DDC lines to meet the I C timing specifications with the minimum pull-up resistor of
1.5kΩ.
2
For this reason, the CM2030 was designed with an internal I C accelerator to meet the AC timing specification
even with very long and non-compliant cables.
Rev. 5 | Page 4 of 17 | www.onsemi.com
CM2030
The internal accelerator increases the positive slew rate of the DDC_CLK_OUT and DDC_DAT_OUT lines
whenever the sensed voltage level exceeds 0.3*5V_SUPPLY (approximately 1.5V). This provides faster overall
2
risetime in heavily loaded situations without overloading the multi-drop open drain I C outputs elsewhere.
DYNAMIC PULLUPS (CONT’D)
Figure 2. Dynamic DDC Pullups (Discrete - Top, CM2030 - Bottom; 3.3V ASIC - Left, 5V Cable - Right.)
Figure 2 demonstrates the “worst case” operation of the dynamic CM2030 DDC level shifting circuitry (bottom)
against a discrete NFET common-gate level shifter circuit with a typical 1.5kW pullup at the source (top.) Both
are shown driving an off-spec, but unfortunately readily available 31m HDMI cable which exceeds the 700pF
HDMI specification. Some widely available HDMI cables have been measured at over 4nF.
When the standard I/OD cell releases the NFET discrete shifter, the risetime is limited by the pullup and the
parasitics of the cable, source and sink. For long cables, this can extend the risetime and reduce the margin for
reading a valid “high” level on the data line. In this case, an HDMI source may not be able to read uncorrupted
data and will not be able to initiate a link.
With the CM2030’s dynamic pullups, when the ASIC driver releases its DDC line and the “OUT” line reaches at
least 0.3*VDD (of 5V_SUPPLY), then the “OUT” active pullups are enabled and the CM2030 takes over driving
the cable until the “OUT” voltage approaches the 5V_SUPPLY rail.
The internal pass element and the dynamic pullups also work together to damp reflections on the longer cables
and keep them from glitching the local ASIC.
2
I C LOW LEVEL SHIFTING
In addition to the Dynamic Pullups described in the previous section, the CM2030 also incorporates improved
2
I C low-level shifting on the DDC_CLK_IN and DDC_DAT_IN lines for enhanced compatibility.
Typical discrete NFET level shifters can advertise specifications for low RDS[on], but usually state relatively high
V[GS] test parameters, requiring a 'switch' signal (gate voltage) as high as 10V or more. At a sink current of 4mA
for the ASIC on DDC_XX_IN, the CM2030 guarantees no more than 140mV increase to DDC_XX_OUT, even
with a switching control of 2.5V on LV_SUPPLY.
Rev. 5 | Page 5 of 17 | www.onsemi.com
CM2030
2
When I C devices are driving the external cable, an internal pulldown on DDC_XX_IN guarantees that the VOL
seen by the ASIC on DDC_XX_IN is equal to or lower than DDC_XX_OUT.
Multiport DDC Multiplexing
By switching LV_SUPPLY, the DDC/HPD blocks can be independently disabled by engaging their inherent
“backdrive” protection. This allows N:1 multiplexing of the low-speed HDMI signals without any additional FET
switches.
Consumer Electronics Control (CEC)
The Consumer Electronics Control (CEC) line is a high level command and control protocol, based on a single
wire multidrop open drain communication bus running at approximately 1kHz (See Figure 3). While the HDMI
link provides only a single point-to-point connection, up to ten (10) CEC devices may reside on the bus, and
they may be daisy chained out through other physical connectors including other HDMI ports or other dedicated
CEC links. The high level protocol of CEC can be implemented in a simple microcontroller or other interface with
any I/OD (input/open-drain) GPIO.
CEC
RX
I/OD
GPIO
TX
Figure 3. Typical µC I/OD Driver
To limit possible EMI and ringing in this potentially complex connection topology, the rise- and fall-time of this
line are limited by the specification. However, meeting the slew-rate limiting requirements with additional
discrete circuitry in this bi-directional block is not trivial without an additional RX/TX control line to limit the output
slew-rate without affecting the input sensing (See Figure 4).
CEC
RX
TX
TX_EN
Slew Rate
Limited
3-State Buffer
X
Figure 4. Three-Pin External Buffer Control
Simple CMOS buffers cannot be used in this application since the load can vary so much (total pullup of 27kΩ to
less than 2kΩ, and up to 7.3nF total capacitance.) The CM2030 targets an output drive slew-rate of less than
100mV/ms regardless of static load for the CEC line. Additionally, the same internal circuitry will perform active
termination, thus reducing ringing and overshoot in entertainment systems connected to legacy or poorly
designed CEC nodes.
Rev. 5 | Page 6 of 17 | www.onsemi.com
CM2030
The CM2030’s bi-directional slew rate limiting is integrated into the CEC level-shifter functionality thus allowing
the designer to directly interface a simple low voltage CMOS GPIO directly to the CEC bus and simultaneously
guarantee meeting all CEC output logic levels and HDMI slew-rate and isolation specifications (See Figure 5).
CEC
CEC I/F
µP
CM2030
Figure 5. Integrated CM2030 Solution
The CM2030 also includes an internal backdrive protected static pullup 120µA current source from the
CE_SUPPLY rail in addition to the dynamic slew rate control circuitry.
Figure 6 shows a typical shaped CM2030 CEC output (bottom) against a ringing uncontrolled discrete solution
(top).
Figure 6. CM2030 CEC Output
Rev. 5 | Page 7 of 17 | www.onsemi.com
CM2030
Hotplug Detect Logic
The CM2030 ensures that the local ASIC will properly detect an HDMI compliant Sink. The current sink maintains a local logic “low” when no system is connected.
A valid pullup on the HDMI connector pin will overdrive the internal pulldown and deliver a logic “high” to the
local ASIC.
CM2030
5V_SUPPLY
LV_SUPPLY
IS
HP_IN
3I
HP_OUT
19
S
HDMI CONN
Figure 7. Hotplug Detect Circuit
Rev. 5 | Page 8 of 17 | www.onsemi.com
CM2030
Ordering Information
PART NUMBERING INFORMATION
Pins
Packge
38
Ldaerf-Fnihs
TSSOP-38
OdrniegtPaNumb
1
PtraMikng
CM2030-A0TR
CM2030-A0TR
Note 1: Parts are shipped in Tape & Reel form unless otherwise specified.
Specifications
ABSOLUTE MAXIMUM RATINGS
PARAMETER
VCC5, VCCLV
DC Voltage at any Channel Input
RATING
UNITS
6.0
V
[GND - 0.5] to [VCC + 0.5]
V
65 to +150
°C
Storage Temperature Range
STANDARD (RECOMMENDED) OPERATING CONDITIONS
SYMBOL
PARAMETER
MNI
TYP
MAX
UNITS
5V_SUPPLY
Operating Supply Voltage
5
5.5
V
LV_SUPPLY
Bias Supply Voltage
1
3.3
5.5
V
CE_SUPPLY
Bias Supply Voltage
3
3.3
3.6
V
Operating Temperature Range
40
85
°C
Rev. 5 | Page 9 of 17 | www.onsemi.com
CM2030
ELECTRICAL OPERATING CHARACTERISTICS (SEE NOTE 1)
SYMBOL
ICC5
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Operating Supply Current
5V_SUPPLY = 5.0V,
CEC_OUT = 3.3V, LV_SUPPLY=
3.3V,CE_SUPPLY= 3.3V, DDC=5V;
Note6
300
350
µA
ICCLV
Bias Supply Current
LV_SUPPLY=3.3V; Note 6
60
150
µA
ICCCE
Bias Supply Current
CE_SUPPLY=3.3V, CEC_OUT=0V;
Notes 6 and 7
60
150
µA
Current source on CEC pin
CE_SUPPLY=3.3V,
120
128
µA
65
100
mV
135
175
mA
ICEC
VDROP
111
5V_OUT Overcurrent Out put 5V_SUPPLY=5.0V, IOUT=55mA
Drop
ISC
5V_OUT Short Circuit Cur
rent Limit
5V_SUPPLY=5.0V, 5V_OUT=GND
IOFF
OFF state leakage current,
level shifting NFET
LV_SUPPLY=0V
0.1
5
µA
Current through CEREMOTE_OUT when
powered down
CE-REMOTE_IN = CE_SUPPLY <
CE_REMOTE_OUT
0.1
1.8
µA
Current through TMDS pins
when powered down
All Supplies = 0V; TMDS_[2:0]+/,
TMDS_CK+/ = 4V
0.1
5
µA
All Supplies = 0V; 5V_OUT_PIN =
5V
0.1
5
µA
All Supplies = 0V;
DDC_DAT/CLK_OUT = 5V;
DDC_DAT/CLK_IN = 0V
0.1
5
µA
0.1
5
µA
0.26
0.65
V/µs
26.4
250
µs
4
50
µs
1.5
1.65
V
150
225
mV
0.3
0.4
V
1
µs
IBACKDRIVECEC
IBACKDRIVETMDS
IBACKDRIVE5V_OUT Current through 5V_OUT
when powered down
IBACKDRIVEDDC
Current through
DDC_DAT/CLK_OUT when
powered down
90
IBACKDRIVEHOTPLUG Current through
All Supplies = 0V;
HOTPLUG_DET_OUT when HOTPLUG_DET_OUT = 5V;
powered down
HOTPLUG_IN = 0V
CECSL
CEC Slew Limit
Measured from 10-90% or 90-10%
CECRT
CEC Rise Time
Measured from 10-90%
Assumes a signal swing from 03.3V
CECFT
CEC Fall Time
VACC
Turn On Threshold of I2C/
DDC Accelerator
Measured from 90-10%
Assumes a signal swing from 03.3V
Voltage is 0.3 ±10% X 5V_Supply;
VON(DDC_OUT)
VOL(DDC_IN)
tr(DDC)
Voltage drop across DDC
level shifter
1.35
Note 2
LV_SUPPLY=3.3V, 3mA Sink at
DDCIN, DDCOUT < VACC
Logic Level (ASIC side) when DDC_OUT=0.4V,
I2C/DDC Logic Low Applied; LV_SUPPLY=3.3V, 1.5kΩ pullup on
(I2C pass-through compatibility)
DDC_OUT to 5.0V; Note 2
DDC_OUT Line Risetime,
DDC_IN floating,
VACC < VDDC_OUT <
LV_SUPPLY=3.3V, 1.5kΩ pullup on
Rev. 5 | Page 10 of 17 | www.onsemi.com
CM2030
(5V_Supply-0.5V)
DDC_OUT to 5.0V, Bus
Capacitance = 1500pF
VF
Diode Forward Voltage
VESD
IF = 8mA, TA = 25°C
Top Diode
0.6
0.85
0.95
Bottom Diode
0.6
0.85
0.95
ESD Withstand Voltage (IEC) Pins 4, 7, 10, 13, 20, 21, 22, 23, 24,
V
V
±8
kV
±2
kV
27, 30, 33, TA = 25°C; Note 2
VESD
VCL
ESD Withstand Voltage
Pins 1, 2, 16, 17, 18, 19, 37, 38, TA
(HBM)
= 25°C
Channel Clamp Voltage
Positive Transients
TA=25°C, IPP = 1A, tP = 8/20µS;
Note 5
11.0
V
2.0
V
Any I/O pin to Ground; Note5
1.4
Ω
TA = 25°C
0.01
1
µA
TMDS Channel Input
5V_SUPPLY=5.0V, Measured at
0.9
1.2
pF
Capacitance
1MHz, VBIAS=2.5V
TMDS Channel Input
5V_SUPPLY=5.0V, Measured at
Capacitance Matching
1MHz, VBIAS=2.5V; Note 4
Negative Transients
RDYN
Dynamic Resistance
Positive Transients
TA=25°C, IPP = 1A, tP = 8/20µS
Negative Transients
ILEAK
TMDS Channel Leakage
0.9
Ω
Current
CIN, TMDS
∆CIN, TMDS
CMUTUAL
Mutual Capacitance between 5V_SUPPLY=0V, Measured at
0.05
pF
0.07
pF
10
pF
10
pF
10
pF
signal pin and adja cent signal 1MHz, VBIAS=2.5V
pin
CIN, DDCOUT
CIN, CECOUT
Level Shifting Input Capaci
5V_SUPPLY=0V,
tance, Capacitance to GND
Measured at 100KHz, VBIAS=2.5V
Level Shifting Input Capaci
5V_SUPPLY=0V,
tance, Capacitance to GND
Measured at 100KHz,
Level Shifting Input Capaci
5V_SUPPLY=0V,
tance, Capacitance to GND
Measured at 100KHz,
VBIAS=1.65V
CIN, HPOUT
VBIAS=2.5V
Note 1: Operating Characteristics are over Standard Operating Conditions unless otherwise specified.
Note 2: Standard IEC61000-4-2, CDISCHARGE=150pF, RDISCHARGE=330Ω, 5V_SUPPLY=5V, 3.3V_SUPPLY=3.3V, LV_SUPPLY=3.3V,
GND=0V.
Note 3: Human Body Model per MIL-STD-883, Method 3015, CDISCHARGE=100pF, RDISCHARGE=1.5kΩ, 5V_SUPPLY=5V,
3.3V_SUPPLY=3.3V, LV_SUPPLY=3.3V, GND=0V.
Note 4: Intra-pair matching, each TMDS pair (i.e. D+, D–)
Note 5 These measurements performed with no external capacitor on VP (VP floating)
Note 6: These static measurements do not include AC activity on controlled I/O lines.
Note 7: This measurement does not inclue supply current for the 120µA current source on the CEC pin.
Rev. 5 | Page 11 of 17 | www.onsemi.com
CM2030
Performance Information
Typical Filter Performance (TA=25°C, DC Bias=0V, 50 Ohm Environment)
Figure 8. Insertion Loss vs. Frequency (TMDS_D1– to GND)
Rev. 5 | Page 12 of 17 | www.onsemi.com
CM2030
Application Information
NO T E 4
5V_SUPPLY
RO PT
5V_OUT
CM2020/2030
LV_SUPPLY
TMDS_D2+
TMDS_D2–
{
TMDS_D1+
TMDS_D1–
NOTE 1
TMDS_D0+
TMDS_D0–
TMDS_CK+
TMDS_CK–
ASIC_CEC
2
2
ASIC_SCL
ASIC_SDA
2
2
HOTPLUG_DETECT
1
38
VCEC
2
37
CBYP
3
36
100nF
4
35
TMDS_D2+
5
34
TMDS_GND
6
TMDS_D2–
7
33
32
8
31
TMDS_GND
9
30
TMDS_D1–
10
29
TMDS_D0+
11
28
TMDS_GND
12
27
TMDS_D0–
13
26
TMDS_CK+
14
15
25
TMDS_GND
TMDS_CK–
16
24
23
17
22
18
21
N/C
DDC_CLK
19
20
TMDS_D1+
CE_REMO TE
DDC_DAT
NOTE 3
GND
+5V OUT
HOTPLUG_DET
DCEC
HDMI
Connector
NOTE 6
RD AT
2k Ω
RSCL
2k Ω
EEPROM_CLK
NOTE 5
CEC
27k Ω
EEPR OM_DAT
RCEC
VCEC
RPD
15k Ω
CHP
CV O UT
100nF
NOTE 7
100nF
Figure 9. Typical Application for CM2030
LAYOUT NOTES
1. Differential TMDS Pairs should be designed as normal 100Ω HDMI Microstrip. Single Ended
TM
TM
(decoupled) TMDS traces underneath MediaGuard , and traces between MediaGuard and Connector
should be tuned to match chip/connector IBIS parasitics.
2
Level Shifter signals should be biased with a weak pullup to the desired local LV_SUPPLY. If the local ASIC
includes sufficient pullups to register a logic high, then external pullups may not be needed.
3
TM
Place MediaGuard as close to the connector as possible, and as with any controlled impedance line always
avoid placing any silk-screen printing over TMDS traces.
4
CM2020/CM2030 footprint compatibility - For the CM2030, Pin 37 becomes the VCEC power supply pin for the
slew-rate limiting circuitry. This can be supplied by a 0W jumper to VCEC which should be depopulated to utilize
the CM2020. The 100nF CBYP is recommended for all applications.
5
CEC pullup isolation. The 27k RCEC and a Schottky DCEC provide the necessary isolation for the CEC pullup.
Rev. 5 | Page 13 of 17 | www.onsemi.com
CM2030
Note: This circuitry is used only in the CM2020. Depopulate the components for CM2030 applications in a
CM2020/ CM2030 dual footprint layout.
6
Footprint compatibility - The CM2030 has (built-in) internal backdrive protection.
The CM2020 does not not have internal backdrive protection and requires the external RCEC and DCEC
components.
7
(For CM2030) If CEC firmware is not implemented, do not populate with 0 Ω resistor. If CEC firmware is
implemented, then populate with 0 Ω resistor.
(For CM2020) Populate with 0 Ω resistor in either case.
Application Information (cont’d)
Design Considerations
1. 5V out (pin 38)
Maximum overcurrent protection output drop at 55mA on 5V_OUT is 100mV. To meet HDMI output requirements of 4.8-5.3V, an input of greater than 4.9V should be used (i.e. 5.1V ±4%)
2. DUT On vs. DUT Off
Many HDMI CTS tests require a power off condition on the System Under Test. Many discrete ESD diode
configurations can be forward biased when their VDD rail is lower than the I/O pin bias, thereby exhibiting
TM
extremely high apparent capacitance measurements, for example. The MediaGuard backdrive isolation
circuitry limits this current to less than 5mA, and will help ensure HDMI compliance.
Please review all of the current HDMI design guidelines available at:
http://www.calmicro.com/applications/customer/downloads/current-cmd-mediaguard-designguidelines.zip
Rev. 5 | Page 14 of 17 | www.onsemi.com
CM2030
Mechanical Details
TSSOP-38 Mechanical Specifications
CM2030 devices are supplied in 38-pin TSSOP packages. Dimensions are presented below.
PACKAGE DIMENSIONS
Packge
TSSOP
JDECNo.
MO-153 (Variation BD-1)
Pins
38
Dimenso
Mmiletrs
Ihncse
Mni
Max
Mni
Mxa
A
—
1.20
—
0.047
A1
0.05
0.15
0.002
0.006
b
0.17
0.27
0.007
0.011
c
0.09
0.20
0.004
0.008
D
9.60
9.80
0.378
0.386
E
E1
e
L
6.40 BSC
4.30
0.252 BSC
4.50
0.50 BSC
0.45
0.177
0.020 BSC
0.75
#pertandl
0.169
0.018
0.030
2500 pieces
Ctnolirgmdes:tr
Rev. 5 | Page 15 of 17 | www.onsemi.com
CM2030
Mechanical Package Diagrams
TOP VIEW
D
38
37
E
36
35 34
33
32 31
30
29
28
27
26
25 24
23 22
21
20
E1
Pin 1 Marking
1
2
3
4
5
6
7
8
9
10
11
12
13
14 15
16
17
18
19
SIDE VIEW
A
SEAT ING
PLANE
A1
b
e
END VIEW
c
L
Package Dimensions for TSSOP-38
Rev. 5 | Page 16 of 17 | www.onsemi.com
CM2030
Tape and Reel Specifications
PART NUMBER
CM2030
PACKAGE SIZE
POCKET SIZE (mm)
TAPE WIDTH
REEL
QTY PER
(mm)
B0 X A0 X K0
W
DIAMETER
REEL
9.70 X 6.40 X 1.20
10.20 X 6.90 X 1.80
16mm
330mm (13")
2500
Po
Top
Cover
Tape
P0
P1
4mm
12mm
10 Pitches Cumulative
Tolerance On ape
T
±0.2 mm
Ao
W
Bo
Ko
For tape feeder reference
only including draf
t.
Concentric around B.
Embossment
P1
Center Lines
of Cavity
User Direction of Feed
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