Optimod-Surround 8685 V1.0 Operating Manual - Orban

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1-12 INTRODUCTION ORBAN MODEL 8685 can do from the 8685’s front panel controls. The program displays all of the 8685’s meters on the computer screen to aid remote adjustment. Because of the large numbers of meters and controls in the 8685, we expect that most users will prefer to operate it via PC Remote. RS-485 Serial Ports There are two RS-485 serial ports on the rear panel (serial ports #2 and #3). These can operate up 115 kbps. These can accept and emit Dolby® AC3 metadata. RS-232 Serial Port 8685 PC Remote can communicate at up to 115 kbps direct connection between the computer and the 8685 through their RS-232 serial ports. RJ45 Ethernet Connector The 8685 can be connected to any Ethernet network that supports the TCP/IP protocol. See page 2-45 for instructions on how to control the 8685 via the RS-232 and Ethernet ports via a terminal emulator and page 2-65 for instructions on how to connect to the 8685 via its PC Remote application for Windows. Optional HD-SDI Input/Output The optional HD-SDI I/O module offers supports SD-SDI (per SMPTE 259M); 1.5 Gbit/s HD-SDI (per SMPTE 292M; up to 720p and 1080i) and 3.0 Gbit/s single-wire HD-SDI (per SMPTE 424M; 1080p). The SDI I/O can de-embed up to eight channels of audio, send them to the 8685’s DSP for audio processing, and then re-embed them with video that has been delayed to maintain AV-sync. There are four variants (see Optional HD-SDI Input/Output Interface Module on page 6-3 for details). The HD-SDI module can accommodate Dolby-E® decoding and encoding via optional plug-in modules. A relay provides hard-wire safety bypass from the SDI input to the SDI output in case of hardware failure. Routing Audio to and from the 8685 Audio links are used in different ways. Performance requirements differ depending on the application: • A link that passes unprocessed audio to drive the OPTIMOD 8685 should have very low noise and low non-linear distortion, but its transient response is not important.
OPTIMOD SURROUND PROCESSOR INTRODUCTION 1-13 • A link that passes OPTIMOD 8685’s peak-controlled output does not need as low a noise floor as a link passing unprocessed audio. However, if the application calls for high average modulation, the link’s transient response is critical. • A link that passes OPTIMOD 8685’s peak-controlled output after it has been coded by the transmission codec requires bit-accurate transmission of the transmission codec’s output. In DTV applications, the 8685 will typically drive a Dolby Digital encoder at the studio. The link will pass the Dolby Digital encoder’s output to the transmitter, either directly or multiplexed onto a transport stream. Using Lossy Data Reduction before the 8685’s Input Many broadcasters are now using lossy data reduction algorithms like MPEG-1 Layer 2, Layer 3, or AAC to increase the storage time of digital playback media and to transmit audio. Sometimes, several encode/decode cycles will be cascaded before the material is finally delivered to OPTIMOD 8685’s input. All such algorithms operate by increasing the quantization noise in discrete frequency bands. If not psychoacoustically masked by the program material, this noise may be perceived as distortion, “gurgling,” swishing, or other interference. Psychoacoustic calculations are used to ensure that the added noise is masked by the desired program material and not heard. Cascading several stages of such processing can raise the added quantization noise above the threshold of masking, making it audible. In addition, at least one other mechanism can cause the noise to become audible at the radio. OPTIMOD 8685’s multiband limiter performs an “automatic reequalization” function that can significantly change the frequency balance of the program (sometimes by more than 10 dB). This can cause noise that would otherwise have been masked to become unmasked because the psychoacoustic masking conditions under which the masking thresholds were originally computed have changed. Accordingly, if you use lossy data reduction before the 8685, you should use the highest data rate possible. This maximizes the headroom between the added noise and the threshold where it will be heard. In addition, you should minimize the number of encode and decode cycles because each cycle moves the added noise closer to the threshold where the added noise is heard. For MPEG Layer 2 encoding, we recommend 384kb/second or higher. Links from the 8685’s Output to a Transmission Encoder or Transmitter When used as a transmission processor, the 8685’s output should be connected to the encoder or transmitter (like Dolby’s DP569 Dolby Digital encoder) so that the link introduces no change in OPTIMOD 8685’s output bitstream. A simple AES3id connection is ideal. Alternatively, an uncompressed digital link will pass the 8685’s output with little or no degradation if the link does not truncate word length (from 20 to 16 bits, for example) and does not require downward sample rate conversion. The 8685’s look-ahead limiters tightly control peak levels at the 8685’s outputs. Lossy compression following the 8685’s output can decrease system performance because the compression adds peak level overshoots. Such links must therefore be carefully qualified before you use them to carry the peak-controlled output of OPTIMOD 8685 to the transmitter. For example, the MPEG Layer 2 algorithm can increase peak
Page 1 and 2: Operating Manual OPTIMOD 8685 Surro
Page 3 and 4: IMPORTANT SAFETY INSTRUCTIONS All t
Page 5 and 6: Manual PLEASE READ BEFORE PROCEEDIN
Page 7 and 8: Operating Manual OPTIMOD 8685 Surro
Page 9 and 10: LIMITED WARRANTY...................
Page 11 and 12: Advanced Two-Band Controls ........
Page 13 and 14: CIRCUIT DESCRIPTION................
Page 15 and 16: Function Description Drawing Page H
Page 17 and 18: C CALM Act 1- · 3 CBS Loudness Lev
Page 19 and 20: dual-mono mode 2- · 34 dull sound
Page 21 and 22: Reassembling 4- · 7 LCD display 6-
Page 23 and 24: DSP board 6- · 22 Encoder board 6-
Page 25 and 26: Resetting 8585 2- · 44 resolution
Page 27 and 28: Changing via terminal program 2- ·
Page 29 and 30: OPTIMOD SURROUND PROCESSOR INTRODUC
Page 39: OPTIMOD SURROUND PROCESSOR INTRODUC
Page 53: OPTIMOD SURROUND PROCESSOR INTRODUC
Page 56 and 57: 2-2 INSTALLATION ORBAN MODEL 8685 C
Page 58 and 59: 2-4 INSTALLATION ORBAN MODEL 8685 P
Page 60 and 61: 2-6 INSTALLATION ORBAN MODEL 8685 A
Page 62 and 63: 2-8 INSTALLATION ORBAN MODEL 8685
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2-36 INSTALLATION ORBAN MODEL 8685
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OPTIMOD SURROUND PROCESSOR OPERATIO
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OPTIMOD SURROUND PROCESSOR MAINTENA
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OPTIMOD MAINTENANCE 4-3 F) Disconne
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OPTIMOD MAINTENANCE 4-5 11. Removin
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OPTIMOD MAINTENANCE 4-7 18. Replaci
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OPTIMOD MAINTENANCE 4-9 most freque
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OPTIMOD MAINTENANCE 4-11 Test Proce
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OPTIMOD MAINTENANCE 4-13 D) LOCATE
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OPTIMOD MAINTENANCE 4-15 SMPTE Rise
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5-2 TROUBLESHOOTING ORBAN MODEL 868
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6-2 TECHNICAL DATA ORBAN MODEL 8685
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J10 NOTE: D7 and D8 are not populat
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1 10 9 8 7 6 4 3 2 5 C +3.3 VDC Req
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+3.3 VDC 5 2 MECC4 3 4 MECC6 6 MECC
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+5 VDC 5 5 +2.5 VDC 4 4 34 42 43 48
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From Base Board 1 2 3 4 5 N/C 6 N/C
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+5V_PS1 CR1 SMAJ5.0CA +5V_PS2 CR2 S
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+ C703 10UF C725 0.1UF POWER SUPPLY
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DSP CONTROL INTERFACE 62375.000.01.
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(SHT7) (SHT7) (SHT6) (SHT6) (SHT6)
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L703 HZ0805G102R-10 C703 +3.3V 0.1U
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J2 1 2 3 4 5 6 7 8 9 10 11 12 13 14
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From Interface Board J2 Pin 4 is au
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GND 1 +5VD 4 VCC GND 2 IC201 /TOVER
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J300A BNC DUAL with CAPACITOR UPPER
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IN-CIRCUIT SERIAL PROGRAMMING INTER
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+5VD Y902 1 2 DGND1 +3.3V_CLK 25.00
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+2.5V DGND +2.5V DGND +2.5V DGND +2
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+2.5V DGND_CLNR + C1300 47uF/10V +1
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RS485-SDI INTERFACE DGND J200 2 4 6
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Optimod-Surround 8685 V1.0 Operating Manual - Orban

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