Index (2-9th byte)

This command is used to specify index of the input channels with 8 bytes of the ASCII code.

Caution

If number of index characters does not reach the 8 bytes, be sure to fill the blanks with the space (20[H]).

MIC INPUT fader (10th byte)

This command is used to set the MIC1/WL1 to MIC6/LINE2 channels’ assign to the GROUP FADER with the 8-bit data. Set 1 to implement assign. Set 0 not to implement assign.

Bit-6 and bit-7 are fixed all the time.

bit7

bit6

bit5

bit4

bit3

bit2

bit1

bit0

0

1

MIC6/

MIC5/

MIC4

MIC3

MIC2/

MIC1/

 

 

LINE2

LINE1

 

 

WL2

WL1

LINE INPUT fader (11th byte)

This command is used to set the LINE3 and 4 channels’ assign to the GROUP FADER with the 8-bit data. Set 1 to implement assign. Set 0 not to implement assign.

Bit-2 to bit-7 are fixed all the time.

bit7

bit6

bit5

bit4

bit3

bit2

bit1

bit0

0

1

0

0

0

0

LINE4

LINE3

LINE OUTPUT1-6 fader (12th byte)

This command is used to set the LINE OUTPUT1 to 6 channels’ assign to the GROUP FADER with the 8-bit data. Set 1 to implement assign. Set 0 not to implement assign.

Bit-6 and bit-7 are fixed all the time.

bit7

bit6

bit5

bit4

bit3

bit2

bit1

bit0

0

1

LINE

LINE

LINE

LINE

LINE

LINE

 

 

OUTPUT6

OUTPUT5

OUTPUT4

OUTPUT3

OUTPUT2

OUTPUT1

LINE OUTPUT7,8 fader (13th byte)

This command is used to set the LINE OUTPUT7 and 8 channels’ assign to the GROUP FADER with the 8-bit data. Set 1 to implement assign. Set 0 not to implement assign.

Bit-2 to bit-7 are fixed all the time.

bit7

bit6

bit5

bit4

bit3

bit2

bit1

bit0

0

1

0

0

0

0

LINE

LINE

 

 

 

 

 

 

OUTPUT8

OUTPUT7

Caution

Do no assign the INPUT fader and the OUTPUT fader to the GROUP FADER of the same channel.

Example: When setting the MASTER A as shown below.

Index

: MIC

MIC INPUT fader

: Assign the MIC1/WL1 through MIC4.

 

: MIC5/LINE1 and MIC6/LINE2 are not assigned.

LINE INPUT fader

: LINE 3 and 4 INPUTs are not assigned.

LINE OUTPUT1-6 fader

: LINE OUTPUT1 through 6 are not assigned.

LINE OUTPUT7,8 fader

: LINE OUTPUT7 and 8 are not assigned.

43[H] 47[H] 46[H] 41[H] 30[H] 4D[H] 49[H] 43[H] 20[H] 20[H] 20[H] 20[H] 20[H] 4F[H] 40[H] 40[H] 40[H] 0D[H] (‘ C G F A M I C s s s s s O @ @ @ CR’)

s” indicates the space.

– 30 –

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Image 30
Sony RS-232C manual Index 2-9th byte, MIC Input fader 10th byte, Line Input fader 11th byte, Line OUTPUT1-6 fader 12th byte

RS-232C specifications

The Sony RS-232C is a renowned communication standard that has been widely utilized in various electronic devices, enabling serial communication between computers and peripheral devices. This protocol is integral in various applications, including industrial automation, medical equipment, and consumer electronics.

One of the main features of the Sony RS-232C is its simplicity and ease of use. The standard utilizes a basic serial communication method, allowing for asynchronous data transmission. This means that data can be sent one bit at a time over a single channel, ensuring reliable communication over short distances, typically up to 50 feet, although longer distances can be achieved with proper cable management and signal boosters.

The technology behind the RS-232C standard employs voltage levels to represent binary data. Logic level zero is represented by a voltage between -3 to -25 volts, while logic level one is between +3 to +25 volts. This voltage differential is crucial for distinguishing between 'on' and 'off' states in electronic signaling. The standard supports data rates of up to 115.2 kbps, making it suitable for various applications, although it is generally limited in speed when compared to modern communication standards like USB or Ethernet.

In terms of characteristics, the Sony RS-232C supports both full-duplex and half-duplex communication, allowing for simultaneous transmission and reception of data, or one-directional data transfer, respectively. The protocol also includes control signals for flow control, such as RTS (Request to Send) and CTS (Clear to Send), which help manage data transmission and prevent data loss due to buffer overflow.

The RS-232C standard has 25-pin and 9-pin connector configurations, although many devices now utilize the more compact 9-pin DIN format. This legacy standard remains prevalent in industrial settings, as many devices still use RS-232 connections.

Despite the emergence of more advanced communication protocols, the reliability and robustness of the Sony RS-232C ensure that it remains an enduring choice for numerous applications. Its straightforward configuration, coupled with extensive documentation and support, makes it a favorable option for both new installations and the maintenance of legacy systems in various industries. As technology continues to evolve, the RS-232C standard remains a testament to the enduring principles of reliable communication.