ETC DRX3960A

ADVANCE INFORMATION
DRX 3960A
Digital Receiver
Front-end
Edition Feb. 8, 2001
6251-510-2AI
MICRONAS
DRX 3960A
ADVANCE INFORMATION
Contents
Page
Section
Title
4
4
5
6
7
7
7
7
1.
1.1.
1.2.
1.3.
1.3.1.
1.3.2.
1.3.3.
1.3.4.
Introduction
Features
Quick Reference Data
Analog TV Application
Initialization for Analog TV
Multistandard Configuration for B/G, L, I, D/K and M/N
Multistandard Configuration for L’
FM Radio
8
8
8
8
8
8
8
8
8
2.
2.1.
2.2.
2.3.
2.4.
2.5.
2.6.
2.7.
2.8.
Functional Description
Input Amplifier with TOP Setting
Carrier Recovery
Channel Filtering and Audio/Video Splitting
Video and Tuner AGC
Group Delay Equalizing
Peaking
SIF AGC
Output Ports
9
9
9
10
10
10
3.
3.1.
3.2.
3.3.
3.4.
3.5.
Standard Specific Filter Curves
Standard B
Standard G
Standard D/K, I, L/L’
Standard M/N
Standard FM
11
11
11
12
13
14
14
14
14
14
15
15
15
16
18
4.
4.1.
4.1.1.
4.1.2.
4.1.3.
4.1.4.
4.1.4.1.
4.1.4.2.
4.1.4.3.
4.2.
4.3.
4.4.
4.4.1.
4.4.2.
4.4.3.
Control Interface
I2C Bus Interface
Device and Subaddresses
Description of CONTROL Register
Protocol Description
Proposals for General DRX 3960A I2C Telegrams
Symbols
Write Telegrams
Read Telegrams
List of Control Registers
List of Status Registers
Description of User Registers
Write Register on I2C Subaddress 03hex
Write Register on I2C Subaddress 10hex
Read Register on I2C Subaddress 11hex
19
19
19
21
22
23
5.
5.1.
5.2.
5.3.
5.4.
5.5.
Specifications
Outline Dimensions
Pin Connections and Short Descriptions
Pin Descriptions
Pin Configuration
Electrical Characteristics
2
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ADVANCE INFORMATION
DRX 3960A
Contents, continued
Page
Section
Title
23
23
24
24
24
5.5.1.
5.5.2.
5.5.3.
5.5.4.
5.6.
Absolute Maximum Ratings
Recommended Operating Conditions
Recommended Crystal Characteristics
Recommended Tuner Characteristics
Characteristics
28
6.
Application Circuit
30
7.
Data Sheet History
Micronas
3
DRX 3960A
ADVANCE INFORMATION
Digital Receiver Front-end
Release Note: Revision bars indicate significant
changes to the previous edition.
1. Introduction
The Digital Receiver Front-end DRX 3960A performs
the entire multistandard Quasi Split Sound (QSS) TV
IF processing, AGC, video demodulation, and generation of the second sound IF (SIF) with only one SAW
filter. The IC is designed for applications in TV sets,
VCRs, PC cards, and TV tuners.
The alignment-free DRX 3960A needs no special
external components. All control functions and status
registers are accessible via I2C bus interface. Therefore, it simplifies the design of high-quality, highly standardized IF stages.
Due to its mixed signal structure and the digital
demodulation, the IC offers unique features and is prepared for digital TV.
– Standard specific digital picture carrier recovery:
• alignment-free
• quartz-stable and accurate
• stable frequency lock at 100% modulation and
overmodulation up to 150%
• quartz-accurate AFC information
– Programmable standard specific digital group delay
equalizing
– Automatically frequency-adjusted Nyquist slope,
therefore optimal picture and sound performance
over complete lock in frequency range
– Standard-specific digital AGC and delayed tuner
AGC with programmable tuner Take Over Point
– Fast AGC due to linear structure
– Adaptive back porch control, therefore fast positive
modulation AGC
– No sound traps needed at video output
– Second SIF output with standard dependent pre-filtering and amplitude controlled output level
– Optimal sound SNR due to carrier recovery without
quadrature distortions
1.1. Features
– FM radio capability without external components
and with standard TV tuner
– Multistandard QSS IF processing with a single SAW
– Highly reduced amount of external components (no
tank circuit, no potentiometers, no SAW switching)
– Prepared for digital TV (DVB-C, DVB-T, ATSC)
– Programmable IF frequency
(38.9 MHz, 45.75 MHz, 32.9 MHz, 36.125 MHz etc.)
– I2C bus interface
– Digital IF processing for the following standards:
B/G, D/K, I, L/L’, and M/N
– Standard specific digital post filtering
– Standard specific digital video/audio splitting
fref
DSP
Clock
Generation
D
Filtering
A
TOP
Carrier
Recovery
IF In
TAGC
VAGC
AAGC
Tuner
AGC
D
A
EQU
D
CVBS
A
D
2nd SIF
A
I2C
Fig. 1–1: Block diagram of the DRX 3960A
4
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DRX 3960A
ADVANCE INFORMATION
1.2. Quick Reference Data
Parameter
Min.
Typ.
Max.
Unit
Supply voltage, analog
5
V
Current consumption, analog
110
mA
Supply voltage, digital
3.3
V
Current consumption, digital
60
mA
Input frequency
30
Maximum wanted signal input voltage
minimum TOP gain:
maximum TOP gain:
47
200
20
Remarks
MHz
mVpp
mVpp
Lock in range
0.8
1.0
MHz
MHz
direction adjacent channel
direction own channel
center freq. quartz stable
Intermodulation ratio α1.07
65
dB
blue picture, PSC1=−13dB,
no sound shelf
Weighted video S/N (CCIR567, 10 kHz...5 MHz)
56
58
dB
Unweighted video S/N (10 kHz...5 MHz)
49
51
dB
Weighted sound S/N (black, CCIR468 quasi peak, SC1/SC2)
62/58
dB
dev. = 27 kHz
Weighted sound S/N (FuBK, CCIR468 quasi peak, SC1/SC2)
55/50
dB
dev. = 27 kHz
CVBS output voltage
2
Vpp
programmable
Second IF output voltage
0.8
Vpp
programmable
Delayed Tuner AGC external voltage
Micronas
8
V
5
DRX 3960A
ADVANCE INFORMATION
1.3. Analog TV Application
The Digital Receiver Front-end DRX 3960A is able to
replace a conventional IF IC including several SAWs.
Nevertheless, quasi split sound processing is performed with standard specific internal filtering and
group delay equalizing.
The input signal of the DRX 3960A is the TV IF with its
carrier at:
– 38.9 MHz (B/G, D/K, I, L, and M/N in multistandard
applications)
– 32.9 MHz (L’)
After the desired standard information is transferred
into the DRX 3960A, the following standard specific
procedures are performed:
– Adjacent channel suppression
– Carrier locking including AFC information generation
– Nyquist slope adjustment
– Video/sound splitting
– Video AGC, including delayed tuner AGC
– Group delay post distortion
– Video and sound frequency shaping
– 45.75 MHz (M/N in single standard applications)
– other frequencies are also programmable
– Video demodulation
– Second SIF generation and AGC
– 36.125 MHz (DVB-C or DVB-T in further versions)
These signals are available from conventional tuners.
For pre-filtering, one 8-MHz channel SAW filter must
be used, e.g. the Epcos X6966M. Nevertheless, the
entire multistandard processing is performed. The prefilter limits the signal bandwidth to 8 MHz and suppresses major parts of the adjacent channels.
Similar to conventional analog front-ends, the tuner
gain is controlled by the DRX 3960A. New AGC algorithms have been implemented for superior level tracking for both positive and negative video modulation.
The demodulated CVBS signal and the second sound
IF (SIF) are available as analog output signals.
If an FM radio channel is transferred to the IF inputs,
down-mixed by means of a standard TV tuner, it can
be preselected and further down-mixed by the
DRX 3960A. Thus, a succeeding sound demodulator,
e.g. the MSP, will be able to demodulate that channel.
The DRX 3960A operates with its own quartz or with
appropriate external clocks, e.g.:
– 13.5, 20.25, 27 MHz from an employed video IC
– 1, 4 MHz from the tuner
CVBS
Tuner
SAW
VPC/VCT
DRX 3960A
2nd SIF
Delayed Tuner AGC
MSP
I2C
Fig. 1–2: Multistandard video and sound IF processing with DRX 3960A
6
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ADVANCE INFORMATION
DRX 3960A
1.3.1. Initialization for Analog TV
The DRX 3960A is able to operate with different reference frequencies. If 20.25 MHz is used, REF_SW has
to be connected to ground; additionally, if a lower frequency is used, SYN_REF (control register) has to be
set accordingly. If a higher frequency is used,
REF_SW has to be connected to VDVDD and
SYN_REF has to be set accordingly. In the 20.25 MHz
case, no I2C command is needed.
The standard which should be processed has to be set
via I2C bus.
Additional controlling is only needed if the default values for the remaining write registers are not applicable.
1.3.2. Multistandard Configuration for
B/G, L, I, D/K and M/N
In multistandard applications for B/G, L, I, D/K, and M/N,
the picture carrier frequency at the tuner output should
be 38.9 MHz. The sound carrier frequencies are below
in a distance corresponding to the transmission standard. Thus, all wanted channel components are within
the passband of the SAW and forwarded to the
DRX 3960A. The demodulated and filtered video signal will be available at the CVBS output and the downconverted sound carriers will be available at the 2nd
SIF output.
1.3.3. Multistandard Configuration for L’
In the L standard, the band 1 channels (40 MHz to
65 MHz) have a different frequency configuration.
Their sound carriers are below the according picture
carrier. This sub-standard is called L’. In that case, the
picture carrier frequency at the tuner output should be
32.9 MHz. Using conventional tuners, the sound carrier frequencies in L’ at the tuner output are above the
picture carrier. Thus, again all wanted channel components are within the passband of the SAW.
1.3.4. FM Radio
In FM radio applications, the tuner has to down-convert the wanted channel to 32.4 MHz. Therefore, the
lower slope of the SAW frequency response rejects
adjacent carriers on one side of that channel. The
DRX 3960A further down-converts the wanted channel
to 5.5 MHz. After additional filtering, the signal is fed to
the 2nd SIF output.
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7
DRX 3960A
2. Functional Description
ADVANCE INFORMATION
is higher than 38% of the CVBS amplitude, or lower
than 17%, it is set to the according limit.
2.1. Input Amplifier with TOP Setting
The first block of the DRX 3960A is a low-noise preamplifier. It has a setable gain between 0 and 20 dB for
setting the Tuner take Over Point voltage (TOP). This
adjustment is responsible for optimal tuner operation.
Note: The TOP is the tuner input voltage at which the
IF circuit (e.g. the DRX 3960A) begins to reduce the
tuner gain. Thus, above this voltage the tuner output
voltage remains nearly constant. Of course, the gain of
the tuner is only allowed to be reduced if the S/N is sufficiently high. A level of 60...70 dBµV at the antenna
input is a typical value for the starting point of gain
reduction.
If the video AGC gain is to low, the tuner AGC
increases its output current. Thus, the tuner reduces
its gain.
The actual gain value of both control loops can be read
out (VID_GAIN, TAGC_I) as information about the
input signal strength.
2.5. Group Delay Equalizing
The group delay is set to compensate the pre-distortion of the transmitter. Additionally, the standard settings can be changed by means of four coefficients to
optimize the complete signal path (EQU_0, EQU_1,
EQU_2, EQU_3).
2.2. Carrier Recovery
A digital PLL performs the tracking of the picture carrier and therefore synchronous demodulation.
The lock in range refers to the desired IF frequency
which is chosen according to the programmed TV
standard (e.g. 32.9 MHz at L’ or 38.9 MHz at all other
standards).
The PLL incorporates its own AFC function and provides the frequency offset from the desired IF frequency for external use (CR_FREQ). A special digital
validation algorithm allows long frequency lock at
100% modulation. Additionally, the PLL aligns the digital calculated Nyquist slope to the picture carrier frequency.
2.6. Peaking
To shape the frequency response, a peaking filter is
implemented. The following figure indicates the possible frequency responses:
Video Response [dB]
10
7.5
5
2.5
0
-2.5
-5
Due to its digital implementation, the carrier recovery
is absolutely offset-free, alignment-free, drift-free, and
quartz-accurate.
2.3. Channel Filtering and Audio/Video Splitting
According to the selected standard, channel filtering
(suppression of not wanted signals) is performed internally by digital filters. These filters additionally separate the video and sound components of the desired
channel and transfer them to the according output. The
processing is competitive to conventional QSS systems.
2.4. Video and Tuner AGC
The video AGC controls the CVBS amplitude to a
given value (VID_AMP). This value may be set via I2C
bus.
In positive modulation mode, an adaptive back porch
control (BPC) is activated. If the detected BP reference
8
-7.5
1
2
3
4
5
Frequency [MHz]
Fig. 2–1: Peaking filter frequency response
The peaking value is setable via I2C (VID_PEAK).
2.7. SIF AGC
The SIF AGC controls the level of the sound carrier
output. Four different reference amplitude values are
available (SIF_REF) .
The actual gain (SIF_GAIN) can be read out and set
via I2C.
According to the standard, the time constant is
switched to FM/NICAM (fast AGC) or AM (slow AGC).
2.8. Output Ports
Six general purpose output ports can be switched to
high or low level.
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DRX 3960A
ADVANCE INFORMATION
3. Standard Specific Filter Curves
The external SAW only performes a coarse attenuation of major parts of adjacent channels. The main filtering is done by means of the DSP. The following figures indicate the overall filter curves of the DRX 3960A
including the SAW.
3.1. Standard B
3.2. Standard G
Video Response [dB]
Video Response [dB]
10
10
0
0
-10
-10
-20
-20
-30
-30
-40
-40
-50
-50
-60
-60
2
4
6
8
10
2
4
6
SIF Response [dB]
SIF Response [dB]
10
10
0
0
-10
-10
-20
-20
-30
-30
-40
-40
-50
-50
-60
-60
4
6
8
10
Frequency [MHz]
Micronas
10
Frequency [MHz]
Frequency [MHz]
2
8
2
4
6
8
10
Frequency [MHz]
9
DRX 3960A
ADVANCE INFORMATION
3.3. Standard D/K, I, L/L’
3.4. Standard M/N
Video Response [dB]
Video Response [dB]
10
10
0
0
-10
-10
-20
-20
-30
-30
-40
-40
-50
-50
-60
-60
2
4
6
8
10
2
4
6
Frequency [MHz]
SIF Response [dB]
10
Frequency [MHz]
SIF Response [dB]
10
10
0
0
-10
-10
-20
-20
-30
-30
-40
-40
-50
-50
-60
-60
2
8
4
6
8
10
Frequency [MHz]
2
4
6
8
10
Frequency [MHz]
3.5. Standard FM
SIF Response [dB]
10
0
-10
-20
-30
-40
-50
-60
2
4
6
8
10
Frequency [MHz]
10
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DRX 3960A
ADVANCE INFORMATION
4. Control Interface
4.1. I2C Bus Interface
4.1.1. Device and Subaddresses
The DRX 3960A is controlled via the I2C bus slave
interface.
The IC is selected by transmitting one of the
DRX 3960A device addresses. In order to allow up to
three ICs to be connected to a single bus, an address
select pin (ADR_SEL) has been implemented. With
ADR_SEL pulled to high, low, or left open, the
DRX 3960A responds to different device addresses. A
device address pair is defined as a write address and a
read address.
Writing is done by sending the device write address,
followed by the subaddress byte, two address bytes,
and two data bytes. Reading is done by sending the
write device address, followed by the subaddress byte
and two address bytes. Without sending a stop condition, reading of the addressed data is completed by
sending the device read address and reading two
bytes of data.
Due to the internal architecture of the DRX 3960A, the
IC cannot react immediately to an I2C request. The
typical response time is about 0.3 ms. If the
DRX 3960A cannot accept another complete byte of
data until it has performed some other function (for
example, servicing an internal interrupt), it will hold the
clock line low to force the transmitter into a wait state.
The maximum wait period during normal operation
mode is less than 1 ms.
Table 4–1: I2C Bus Device Addresses
ADR_SEL
Low
High
Left Open
Mode
Write
Read
Write
Read
Write
Read
Device address
82hex
83hex
86hex
87hex
8Ahex
8Bhex
Table 4–2: I2C Bus Subaddresses
Name
Binary Value
Hex Value
Mode
Function
CONTROL
0000 0000
00
Read/Write
Write
Read
PORT
0000 0011
03
Write
output port address
WR_DRX
0001 0000
10
Write
write address
RD_DRX
0001 0001
11
Write
read address
Micronas
: Software reset of DRX
: Hardware error status of DRX
11
DRX 3960A
ADVANCE INFORMATION
4.1.2. Description of CONTROL Register
Table 4–3: CONTROL as a Write Register
Name
Subaddress
Bit[15] (MSB)
Bits[14:0]
CONTROL
00hex
1 : RESET
0 : normal
0
Table 4–4: CONTROL as a Read Register
Name
Subaddress
Bit[15] (MSB)
Bit>@
BitV>@
CONTROL
00hex
Reset status after last reading of CONTROL:
0 : no reset occurred
1 : reset occurred
Internal hardware status:
0 : no error occurred
1 : internal error occurred
not of interest
Reading of CONTROL will reset the bits[15,14] of CONTROL. After Power-on, bit[15] of CONTROL will be set; it must be
read once to be reset.
12
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DRX 3960A
ADVANCE INFORMATION
4.1.3. Protocol Description
Write protocol
S
Wait
write
device
address
ACK sub-addr ACK addr-byte ACK addr-byte ACK data-byte- ACK data-byte ACK P
high
low
high
low
Read protocol
S
Wait
write
device
address
ACK sub-addr ACK addr-byte ACK addr-byte ACK S
high
low
read
device
address
Wait
ACK data-byte- ACK data-byte NAK P
high
low
Write to Control or Test Registers
S
Wait
write
device
address
ACK sub-addr ACK data-byte ACK data-byte ACK P
high
low
Write to Port Registers
S
Wait
write
device
address
Note: S =
P=
ACK =
NAK =
Wait =
ACK sub-addr ACK data-byte ACK P
I2C bus Start Condition from master
I2C bus Stop Condition from master
Acknowledge-Bit: LOW on I2C_DA from slave (= DRX, light gray)
or master (= controller dark gray)
Not Acknowledge-Bit: HIGH on I2C_DA from master (dark gray) to indicate ‘End of Read’
or from DRX indicating internal error state
I2C clock line is held low, while the DRX is processing the I2C command. This waiting time is
max. 1 ms
1
0
I2C_DA
S
P
I2C_CL
Fig. 4–1: I2C bus protocol (MSB first; data must be stable while clock is high)
Micronas
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DRX 3960A
ADVANCE INFORMATION
4.1.4. Proposals for General DRX 3960A I2C Telegrams
4.1.4.1. Symbols
daw
dar
<
>
aa
dd
write device address (82hex, 86hex or 8Ahex)
read device address (83hex, 87hex or 8Bhex)
Start Condition
Stop Condition
Address Byte
Data Byte
4.1.4.2. Write Telegrams
<daw 00 d0 00>
<daw 10 aa aa dd dd>
write to CONTROL register
write data into DRX
4.1.4.3. Read Telegrams
<daw 11 aa aa <dar dd dd>
read data from DRX
4.2. List of Control Registers
Table 4–5: List of Control Registers
Write Register
Address
(hex)
Bits
Description
Reset
(hex)
Output level of Ports
0
01 03
I2C Subaddress = 03hex ; Register is not readable.
Output ports
no
[5:0]
I2C Subaddress = 10hex ; Register are not readable.
Standard select
00 20
[11:0]
Transmission standard
Level settings
10 01
[9:0]
[VID_PEAK, SIF_REF, VID_AMP]
Reference divider
10 10
[8:0]
[for 4 MHz, 13 MHz, 20.25 MHz, 27 MHz or other
REF_SW = high
REF_SW = low]
10D
0CA
Tuner take over point
10 12
[3:0]
[0 dB ... 20 dB]
3
Equalizer Coe. 0
10 70
[9:0]
Equalizer coefficient
025
Equalizer Coe. 1
10 71
[8:0]
Equalizer coefficient
197
Equalizer Coe. 2
10 72
[8:0]
Equalizer coefficient
0C5
Equalizer Coe. 3
10 73
[8:0]
Equalizer coefficient
12E
14
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DRX 3960A
ADVANCE INFORMATION
4.3. List of Status Registers
Table 4–6: List of Status Registers
Read Register
Address
(hex)
Bits
Description
I2C Subaddress = 11hex ; Register are not writable
VIDEO_GAIN
10 05
[10:0]
Actual gain of the video AGC
TAGC_I
10 06
[11:0]
Actual tuner current
SIF_GAIN
10 0A
[10:0]
Internal actual gain of the SIF AGC
CR_FREQ
10 0B
[8:1]
Frequency deviation referred to reference IF frequency
4.4. Description of User Registers
4.4.1. Write Register on I2C Subaddress 03hex
Table 4–7: Write Register on I2C Subaddress 03hex
I2C-Subaddress
(hex)
Function
Name
no
Output Port Level
PORT
bit[5]
bit[4]
bit[3]
bit[2]
bit[1]
bit[0]
Micronas
Level at output port 5
Level at output port 4
Level at output port 3
Level at output port 2
Level at output port 1
Level at output port 0
15
DRX 3960A
ADVANCE INFORMATION
4.4.2. Write Register on I2C Subaddress 10hex
Table 4–8: Write Register on I2C Subaddress 10hex
I2C-Subaddress
(hex)
Function
Name
00 20
Standard select
STANDARD_SEL
Defines TV standard which is to be processed
bit[15:0]
10 01
00 00hex
00 01hex
00 02hex
01 03hex
00 03hex
00 04hex
00 09hex
01 09hex
00 0Ahex
00 40hex
reserved
reserved
M/N
B (default)
G
D/K
L
L’
I
FM
Level settings
Defines the different output levels and frequency response
16
bit[4:0]Video frequency response deviation at 5 MHz
−8
−11.0 dB
−7
−9.0 dB
...
...
−2
−2.1 dB
−1
−1.0 dB
0
0 dB
1
0.8 dB
(default)
2
1.5 dB
3
2.1 dB
...
...
14
8.1 dB
15
8.3 dB
VID_PEAK
bit[6:5]
Reference value for SIF maximum amplitude:
0
1000 mVpp(default)
1
700 mVpp
2
500 mVpp
3
350 mVpp
SIF_REF
bit[8:7]
Reference value for video amplitude
0
2.0 V (default)
1
1.5 V
2
1.0 V
3
0.7 V
VID_AMP
Micronas
DRX 3960A
ADVANCE INFORMATION
Table 4–8: Write Register on I2C Subaddress 10hex
I2C-Subaddress
(hex)
Function
Name
10 10
Reference divider setting
SYN_REF
The DRX 3960A is able to operate with different reference frequencies. The
reference divider has to be set to the value which divides the reference frequency to 100 kHz.
To prevent malfunction after POR, the default value is set for fref = 27 MHz, if
the pin REF_SW is connected to VDVDD or set for fref = 20.25 MHz, if the pin
REF_SW is connected to GND.
bit[8:0]
10 12
External_Ref_Freq / 100 kHz
27 MHz
10Dhex
20.25 MHz
CAhex
4 MHz
28hex
Tuner Take Over Point (TOP) setting
TOP_SET
Defines the gain of the internal preamplifier to set the TOP
bit[3:0]
10 70
Equalizer coefficient 0
bit[9:1]
bit[0]
10 71
Micronas
do not update coefficients
update coefficients
EQU_1
EQU_2
Coefficient
Equalizer coefficient 3
bit[8:0]
EQU_0
Coefficient
Equalizer coefficient 2
bit[8:0]
10 73
Coefficient
Update bit
0
1
Equalizer coefficient 1
bit[8:0]
10 72
Gain of Preamplifier
0
0 dB
1
1.33 dB
2
2.67 dB
...
8
10 dB (default)
...
14
18.67 dB
15
20 dB
EQU_3
Coefficient
17
DRX 3960A
ADVANCE INFORMATION
4.4.3. Read Register on I2C Subaddress 11hex
Table 4–9: Read Register on I2C Subaddress 11hex
I2C-Subaddress
(hex)
Function
Name
10 05
Actual gain of video AGC
VID_GAIN
bit[10:0]
10 06
Tuner current 0.4 µA/LSB
SIF_GAIN
SIF gain
0.05 dB/LSB
0dB = C8hex
CR_FREQ
Frequency deviation10 kHz/LSB
Lock bit:
1 : Carrier Recovery locked
0 : Carrier Recovery unlocked
Lock Quality
bit[10:0]
18
TAGC_I
AFC
bit[8:1]
bit[0]
10 0C
0dB = C8hex
Actual gain of SIF AGC
bit[10:0]
10 0B
0.05 dB/LSB
Actual gain of tuner AGC
bit[10:0]
10 0A
Video gain
CR_LOCK
< 080hex
strong signal
080hex...700hex weak signal
> 700hex
no signal
Micronas
DRX 3960A
ADVANCE INFORMATION
5. Specifications
5.1. Outline Dimensions
10 x 0.8 = 8 ± 0.1
0.17 ± 0.06
0.8
23
10 ± 0.1
0.34 ± 0.05
13.2 ± 0.2
12
44
0.8
22
34
10 x 0.8 = 8 ± 0.1
33
1
11
2.0 ± 0.1
13.2 ± 0.2
2.15 ± 0.2
10 ± 0.1
0.1
SPGS706000-5(P44)/1E
Fig. 5–1:
44-Pin Plastic Metric Quad Flat Pack
(PMQFP44)
Weight approximately 0.4 g
Dimensions in mm
5.2. Pin Connections and Short Descriptions
NC = not connected, leave vacant
LV = if not used, leave vacant
DVSS = if not used, connect to DVSS
Pin No.
Pin Name
Type
X = obligatory; connect as described in circuit diagram
AHVSS = connect to AHVSS
Supply
Voltage
Connection
Short Description
(If not used)
1
AVSS_ADC
X
Analog ground for ADC
2
AVDD_ADC
X
Analog supply for ADC (+5 V)
3
ANATSTX
I/O
AVDD_FE8
GND
Test pin
4
ANATSTY
I/O
AVDD_FE8
GND
Test pin
5
AVDD_FE8
X
2nd analog supply for the front-end
6
AVSS_FE8
X
2nd analog ground for the front-end
7
AVSS_FE40
X
1st analog ground for the front-end
8
IFINX
X
IF input
9
AVDD_FE40
X
1st analog supply for the front-end (+5 V)
10
IFINY
X
IF input
11
AVSS_FE40
X
1st analog ground for the front-end
12
AVDD_SYN
X
Analog supply for synthesizer (+5 V)
13
AVSS_SYN
X
Analog ground for synthesizer
14
SHIELD
X
Shield GND
Micronas
IN
IN
IN
AVDD_FE40
AVDD_FE40
19
DRX 3960A
Pin No.
Pin Name
ADVANCE INFORMATION
Type
Supply
Voltage
Connection
Short Description
(If not used)
15
TEST0
IN
AVDD_DAC
GND
Test Pin
16
TEST1
IN
AVDD_DAC
GND
Test Pin
17
TEST2
IN
AVDD_DAC
GND
Test Pin
18
CVBS
OUT
AVDD_DAC
X
CVBS output
19
REF_SW
IN
AVDD_DAC
X
Reference frequency switch
20
SIF
OUT
AVDD_DAC
X
2nd SIF output
21
AVDD_DAC
X
DAC supply (+5 V)
22
AVSS_DAC
X
DAC ground
23
TEST_EN
IN
DVDD
GND
Test enable
24
RESETQ
IN
DVDD
X
Reset
25
I2C_SDA
I/O
DVDD
X
I2C data
26
I2C_SCL
I/O
DVDD
X
I2C clock
27
DVDD_CAP
X
Digital supply capacitor
28
DVDD
X
Digital supply (+3.3 V)
29
DVSS
X
Digital ground
30
DVSS_CAP
X
Digital capacitor ground
31
PORT0
OUT
DVDD
LV
Digital output port
32
PORT1
OUT
DVDD
LV
Digital output port
33
TUNER_AGC
OUT
DVDD
X
Tuner AGC current output
34
PORT2
OUT
DVDD
LV
Digital output port
35
PORT3
OUT
DVDD
LV
Digital output port
36
PORT4
OUT
DVDD
LV
Digital output port
37
ADR_SEL
IN
DVDD
X
Address select
38
PORT5
OUT
DVDD
LV
Digital output port
39
DVDD_ADC
X
Digital supply for ADC (+3.3 V)
40
DVSS_ADC
X
Digital ground for ADC
41
XTAL_IN
IN
AVDD_ADC
X
Crystal oscillator
42
XTAL_OUT
I/O
AVDD_ADC
X
Crystal oscillator /
external reference frequency
43
VREF
AVDD_ADC
X
ADC reference voltage
44
SGND
AVDD_ADC
X
ADC reference ground
20
Micronas
ADVANCE INFORMATION
DRX 3960A
5.3. Pin Descriptions
Pin 1, AVSS_ADC − Analog ground for ADC
Pin 2, AVDD_ADC − Analog supply for ADC
This pin must be connected to 5 V.
Pin 3, ANATSTX − Reserved for test
This pin should be connected to analog ground.
Pin 4, ANATSTY − Reserved for test
This pin should be connected to analog ground.
Pin 5, AVDD_FE8 − Analog supply for analog frontend This pin must be connected to 5 V.
Pin 6, AVSS_FE8 − Analog ground for analog frontend
Pin 7, AVSS_FE40 − Analog ground for IF input circuitry.
The layout of the IF input should be symmetrical with
respect to AVDD_FE40.
Pin 8, IFINX − Balanced IF input X
This pin must be connected to SAW output. SAW has
to be placed as close as possible. The layout of the IF
input should be symmetrical with respect to
AVDD_FE40.
Pin 9, AVDD_FE40 − Analog supply for IF input circuitry
This pin must be connected to 5 V. The layout of the IF
input should be symmetrical with respect to
AVDD_FE40.
Pin 10, IFINX − Balanced IF input Y
This pin must be connected to SAW output. SAW has
to be placed as close as possible. The layout of the IF
input should be symmetrical with respect to
AVDD_FE40.
Pin 11, AVSS_FE40 − Analog ground for IF input circuitry
The layout of the IF input should be symmetrical with
respect to AVDD_FE40.
Pin 12, AVDD_SYN − Analog supply for clock synthesizer. This pin must be connected to 5 V.
Pin 13, AVSS_SYN − Analog ground for clock synthesizer.
Pin 14, SHIELD − Analog ground for shielding analog
from digital part.
Pin 15,16,17, TEST0 1 2 − Pins for factory test
Micronas
Pin 18, CVBS − Video output
Output level is set via I2C-Bus. An appropriate video
processor (e.g. VPC etc.) has to be connected to that
pin.
Pin 19, REF_SW− Reference frequency switch. This
input defines the default setting of the reference divider
after POR. For 20.25 MHz applications it has to be
connected to ground, for applications with higher frequencies than 20.25 MHz it must be connected to
3.3 V.
Pin 20, SIF − 2nd sound IF ouput
Output level is set via I2C-Bus. An appropriate sound
processor (e.g. MSP) has to be connected to that pin.
Pin 21, AVDD_DAC − Analog supply for the analog
output DACs
This pin must be connected to 5 V.
Pin 22, AVSS_DAC − Analog Ground for the analog
output DACs
This pin must be connected to ground.
Pin 23, TEST_EN − Test Enable pin
This pin enables factory test modes. For normal operation it must be connected to ground.
Pin 24, RESET − Reset input
For normal operation, a high level is required. A low
level resets the DRX 3960A.
Pin 25, 26, I2C_SDA, I2C_SCL− I2C control bus data
and clock
Pin 27, DVDD_CAP − Digital supply pin
This pin has to be connected to 3.3 V according to the
application circuit.
Pin 28, DVDD − Digital supply pin
This pin has to be connected to 3.3 V according to the
application circuit.
Pin 29, DVSS − Digital ground pin
This pin has to be connected to digital ground according to the application circuit.
Pin 30, DVSS_CAP − Digital ground pin
This pin has to be connected according to the application circuit.
Pin 31, 32, 34, 35, 36, 38, PORT0 1 2 3 4 5 − General
purpose output ports
Their states are controlled via I2C bus.
Pin 33, TUNER_AGC − This pin controls the delayed
tuner AGC. As it is a noise-shaped-I-DAC output, it has
to be connected according to the application circuit.
21
DRX 3960A
Pin 37, ADR_SEL − I2C Bus address select
By means of this pin, one of three device addresses
can be selected.
ADVANCE INFORMATION
5.4. Pin Configuration
DVDD
Pin 39, DVDD_ADC − Digital supply pin for ADC
This pin has to be connected to 3.3 V.
DVSS
DVDD_CAP
DVSS_CAP
I2C_SCL
PORT0
Pin 40, DVSS_ADC − Digital ground pin for ADC.
This pin has to be connected to digital ground.
Pin 41, XTAL_IN − Crystal input pin
If an external clock is used this pin should be left open.
A crystal should be placed as close as possible to this
pin. External capacitors at each crystal pin to ground
are required. It should be verified by layout, that no
supply current is flowing through the ground connection point.
Pin 42, XTAL_OUT − Crystal output pin
If an external clock is used, it has to be connected to
this pin. A crystal should be placed as close as possible to this pin. External capacitors at each crystal pin
to ground are required. It should be verified by layout,
that no supply current is flowing through the ground
connection point.
I2C_SDA
PORT1
RESETQ
TUNER_AGC
TEST_EN
33 32 31 30 29 28 27 26 25 24 23
PORT2
34
22
AVSS_DAC
PORT3
35
21
AVDD_DAC
PORT4
36
20
SIF
ADR_SEL
37
19
REF_SW
PORT5
38
18
CVBS
DVDD_ADC
39
17
TEST2
DVSS_ADC
40
16
TEST1
XTAL_IN
41
15
TEST0
XTAL_OUT
42
14
SHIELD
VREF
43
13
AVSS_SYN
SGND
44
12
AVDD_SYN
DRX 3960A
1
2
3
4
5
6
7
8
9
AVSS_ADC
AVSS_FE40
AVDD_ADC
IFINY
AVDD_FE40
ANATSTX
Pin 43, VREF − Analog reference voltage
This pin must be connected to SGND via a circuitry
according to the application circuit.
Pin 43, SGND − Reference for analog ground
This pin must be connected separately to a single
ground point.
22
10 11
ANATSTY
IFINX
AVDD_FE8
AVSS_FE40
AVSS_FE8
Fig. 5–2: 44-pin PMQFP package
Micronas
DRX 3960A
ADVANCE INFORMATION
5.5. Electrical Characteristics
5.5.1. Absolute Maximum Ratings
Symbol
Parameter
TA
Min.
Max.
Unit
Ambient Operating Temperature
0
70
°C
PTOT
Maximum Power Dissipation
–
833
mW
TS
Storage Temperature
–40
125
°C
VSUPmax
Supply Voltage, all Supply Inputs
–0.3
6
V
Vmax
External Voltage, all VASUP Pins,
(without TUNER_AGC)
–0.3
VASUP+0.3
V
External Voltage, all VDSUP Pins
–0.3
VDSUP+0.3
V
VSUP-tun
Pin Name
External Voltage, I2C
I2C_SDA
I2C_SCL
−0.3
6
V
TUNER_AGC Voltage
TUNER_AGC
–
8
V
Stresses beyond those listed in the “Absolute Maximum Ratings” may cause permanent damage to the device. This
is a stress rating only. Functional operation of the device at these or any other conditions beyond those indicated in
the “Recommended Operating Conditions/Characteristics” of this specification is not implied. Exposure to absolute
maximum ratings conditions for extended periods may affect device reliability.
5.5.2. Recommended Operating Conditions
Symbol
Parameter
Pin Name
Min.
Typ.
Max.
Unit
VASUP
Voltage, Analog Supply Pins
AVDD_ADC
AVDD_FE8
AVDD_FE40
AVDD_SYN
AVDD_DAC
4.75
5.0
5.25
V
VDSUP
Voltage, Digital Supply Pins
DVDD
DVDD_CAP
3.0
3.3
3.6
V
VDSUP_ADC
Voltage, Digital Supply Pins, ADC
DVDD_ADC
3.0
3.3
3.6
V
Vext_I2C
External Voltage I2C
I2C_SDA
I2C_SCL
0.0
–
5.5
V
fXTAL
Clock Frequency
XTAL_IN/
OUT
–
20.25
–
MHz
fexternal
External Clock Frequency Range
XTAL_IN
1
20.25
30
MHz
fssbnoise
SSB-Phase noise of
External Clock Frequency
fratio = 20*Log10
(40.5 MHz/fexternal)
XTAL_IN
–90
fratio
dBc
fm =
1 kHz
The values given under “Characteristics” are valid for these “Recommended Operating Conditions”.
Micronas
23
DRX 3960A
ADVANCE INFORMATION
5.5.3. Recommended Crystal Characteristics
Symbol
Parameter
Min.
Typ.
Max.
Unit
TA
Operating Ambient Temperature
0
–
70
°C
fP
Parallel Resonance Frequency
with Load Capacitance CL = 13 pF
–
20.250000
–
MHz
∆fP/fP
Accuracy of Adjustment
–
–
±100
ppm
∆fP/fP
Frequency Temperature Drift
–
–
±30
ppm
RR
Series Resistance
–
–
25
Ω
C0
Shunt Capacitance
3
–
7
pF
Typ.
Max.
Unit
5.5.4. Recommended Tuner Characteristics
Symbol
Parameter
Min.
atuner
Minimum Gain Control Range
40
Stuner
AGC Control Voltage Sensitivity
dB
50
dB/V
5.6. Characteristics
Symbol
Parameter
Pin
Name
Min.
Typ.
Max.
Unit
Test Conditions
Supply
Idig
Current Consumption, digital
60
mA
Iana
Current Consumption, analog
110
mA
Ptot
Total Power Consumption
750
mW
Digital Input Levels
VDIGIL
Digital Input Low Voltage
VDIGIH
Digital Input High Voltage
ZDIGI
Input Impedance
IDLEAK
Digital Input Leakage Current
VDIGIL
Digital Input Low Voltage
VDIGIH
Digital Input High Voltage
0.8
IADRSEL
Input Current Address Select Pin
−500
TEST_EN
REF_SW
0.2
0.8
VDVDD
−1
ADR_SEL
5
pF
1
µA
0.2
VDVDD
0 V < VINPUT< VDVDD
VDVDD
−220
220
24
VDVDD
500
µA
VADR_SEL= VDVSS
µA
VADR_SEL= VDVDD
Micronas
DRX 3960A
ADVANCE INFORMATION
Symbol
Parameter
Pin
Name
Min.
Typ.
Max.
Unit
Test Conditions
0.4
V
IPORT = 1.6 mA
V
IPORT = −1.6 mA
Digital Output Levels
VPORTL
Digital Output Low Voltage
VPORTH
Digital Output High Voltage
VDVDD 0.4
IPORT
Digital Output Current
−2
PORT 0,
1, 2, 3, 4, 5
2
mA
Reset
VRHL
Reset High Low transition
RESET
1.1
V
VRLH
Reset Low High transition
RESET
2.1
V
VI2CIL
I2C-Bus Input Low Voltage
I2C_CL,
I2C_DA
VI2CIH
I2C-Bus Input High Voltage
0.6
VDVDD
tI2C1
I2C Start Condition Setup Time
120
ns
tI2C2
I2C Stop Condition Setup Time
120
ns
tI2C5
I2C-Data Setup Time
before Rising Edge of Clock
55
ns
tI2C6
I2C-Data Hold Time
after Falling Edge of Clock
55
ns
tI2C3
I2C-Clock Low Pulse Time
500
ns
tI2C4
I2C-Clock High Pulse Time
500
ns
fI2C
I2C-Bus Frequency
VI2COL
I2C-Data Output Low Voltage
II2COH
I2C-Data Output
High Leakage Current
tI2COL1
I2C-Data Output Hold Time
after Falling Edge of Clock
15
ns
tI2COL2
I2C-Data Output Setup Time
before Rising Edge of Clock
100
ns
I2C-Bus
I2C_CL
0.3
I2C_CL,
I2C_DA
VDVDD
1.0
MHz
0.4
V
II2COL = 3 mA
1.0
µA
VI2COH = 5 V
fI2C = 1 MHz
IF Input
Differential Input Impedance
R
C
IFINX,
IFINY
fin
Input Frequency
IFINX,
IFINY
Vwanted
Maximum wanted Signal Input
Voltage
TOP = 0
IFINX,
IFINY
Zin
TOP = 15
SIF
Micronas
Sensitivity
(S/N unweighted = 26 dB)
IFINX,
IFINY
1.6
1
2
2.4
4
kΩ
pF
38.9
47
MHz
FS
200
97
mVpp
dBuV
20
77
mVpp
dBuV
1
mV
fin = 38.9 MHz,
TOP gain = 10 dB
25
DRX 3960A
Symbol
Parameter
ADVANCE INFORMATION
Pin
Name
Min.
Typ.
Max.
Unit
Test Conditions
Low Noise Preamplifier (with Tuner Take Over Point Setting)
TOPmin
Minimum Gain
0
dB
TOPmax
Maximum Gain
20
dB
TOPstep
Stepsize of Gain
1.33
dB
Analog Front-end
Gtol
Total Gain Tolerance
±1
dB
50
kHz
matched inputs
Carrier Recovery
DAFC
Frequency Tolerance
= AFC Accuracy
flock
Lock in range
= frequency true demodulation
range
0.8
1.0
MHz
MHz
direction: adjacent channel
direction: own channel
VIF AGC
fVAGC
Control Bandwidth
BWn
negative modulation
200
Hz
BWp
positive modulation
1
Hz
BWpinc
positive modulation
increasing signal
(white picture)
200
Hz
BWbp
positive modulation
back porch control
200
Hz
Tuner AGC, Current Output
ITAGC
Maximum Output Sink Current
Vsup_tun
Maximum Output Voltage
TUNER_
AGC
680
800
920
µA
8
V
90 % FS
Video Output
Vsync
Sync Level
(minimum DAC value)
Vvidmax
CVBS
1.2
1.4
1.6
V
Maximum Level
(maximum DAC value)
3.8
2.9
2.4
2.0
4.0
3.3
2.7
2.3
4.2
3.7
3.0
2.6
V
@ VID_AMP=0
@ VID_AMP=1
@ VID_AMP=2
@ VID_AMP=3
Vvidpp
Full Scale Voltage
2.4
1.7
1.2
0.8
2.6
1.9
1.3
0.9
2.8
2.1
1.4
1.0
Vpp
@ VID_AMP=0
@ VID_AMP=1
@ VID_AMP=2
@ VID_AMP=3
f-1dBvid
Cutoff Frequency
6
MHz
CLoad < 30 pF,
RLoad_AC > 1 kΩ
Routvid
Output Resistance
Ω
f < 6 MHz
SNRvidw
Weighted Video S/N
56
58
dB
Weighted video S/N
(CCIR567, 10 kHz...5 MHz)
SNRvidu
Unweighted Video S/N
49
51
dB
Unweighted video S/N
(10 kHz...5 MHz)
α1.07
Intermodulation ratio
65
dB
blue picture, PSC1=-13dB,
no sound shelf
50
α1.07= PCC-P1.07 +3dB
26
Micronas
DRX 3960A
ADVANCE INFORMATION
Symbol
Parameter
Pin
Name
Min.
Typ.
Max.
Unit
Test Conditions
Vpp
@ SIF_REF=0
@ SIF_REF=1
@ SIF_REF=2
@ SIF_REF=3
MHz
CLoad < 30 pF,
RLoad_AC > 1 kΩ
Ω
f < 6 MHz
Sound IF Output
Vsifpp
Full Scale Voltage
f-1dBsif
Cutoff Frequency f-1dB
Routsif
Output Resistance
SNRb
Weighted Sound S/N
SC1/SC2
62/58
dB
black picture, CCIR 468
SNRw
Weighted Sound S/N
SC1/SC2
62/58
dB
white picture, CCIR 468
SNRfubk
Weighted Sound S/N
SC1/SC2
55/50
dB
FuBK picture, CCIR 468
Micronas
SIF
1.5
1.1
0.8
0.6
6
50
27
DRX 3960A
ADVANCE INFORMATION
6. Application Circuit
REF_SW
28
Micronas
ADVANCE INFORMATION
Micronas
DRX 3960A
29
DRX 3960A
ADVANCE INFORMATION
7. Data Sheet History
1. Advance Information: “DRX 3960A Digital Receiver
Front-end”, Aug. 10, 2000, 6251-510-1AI. First release
of the advance information.
2. Advance Information: “DRX 3960A Digital Receiver
Front-end”, Feb. 8, 2001, 6251-510-2AI. Second
release of the advance information.
Major changes:
– reduction of front-end gain
– positive detection bit removed
– output level setting changed
– lock detection bit added
Micronas GmbH
Hans-Bunte-Strasse 19
D-79108 Freiburg (Germany)
P.O. Box 840
D-79008 Freiburg (Germany)
Tel. +49-761-517-0
Fax +49-761-517-2174
E-mail: [email protected]
Internet: www.micronas.com
Printed in Germany
Order No. 6251-510-2AI
30
All information and data contained in this data sheet are without any
commitment, are not to be considered as an offer for conclusion of a
contract, nor shall they be construed as to create any liability. Any new
issue of this data sheet invalidates previous issues. Product availability
and delivery are exclusively subject to our respective order confirmation
form; the same applies to orders based on development samples delivered. By this publication, Micronas GmbH does not assume responsibility for patent infringements or other rights of third parties which may
result from its use.
Further, Micronas GmbH reserves the right to revise this publication
and to make changes to its content, at any time, without obligation to
notify any person or entity of such revisions or changes.
No part of this publication may be reproduced, photocopied, stored on a
retrieval system, or transmitted without the express written consent of
Micronas GmbH.
Micronas