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TP11362AV 数据表(PDF) 3 Page - National Semiconductor (TI) |
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TP11362AV 数据表(HTML) 3 Page - National Semiconductor (TI) |
3 / 16 page Pin Descriptions (Continued) QSEL0, QSEL1 ADPCM bit rate select inputs. The QSEL0 and QSE1 signals are strobed in with the falling edge of CE. The QSEL0 and QSEL1 select the conversion bit rate of the PCM data just clocked in at the TSI input or the bit rate of the ADPCM data just clocked in at the RSI input. See Table 1. RSTB Chip reset input. A low to high transition at RSTB initiates the reset sequence which initializes the channel variables for all eight channels. A logic low applied to this pin sets the transcoder into a low power dissipation mode. RSTB should be pulled high for normal operation. TST0, TST1, TST2 Test inputs for factory testing purposes. TST0–2 should be tied low for normal operation. V CC1,VCC2 Positive power supply input pins. V CC = 5V ±5%. A 0.1 µF ceramic bypass capacitor should be connected between V CC1 and GND1, and VCC2 and GND2. GND1, GND2 Ground input pins. NC Not connected. Functional Description Adaptive Differential Pulse Code Modulation (ADPCM) is a transcoding algorithm for voice and voice band data trans- mission. The use of ADPCM reduces the channel bandwidth requirements from the standard 64 kbps PCM signal by a factor of two or more. It is used for converting a 64 kbps A-law or µ-law PCM channel to and from a 40, 32, 24 or 16 kbps channel. The 8-bit PCM signal is reduced to 2–5 bits ADPCM signal depending on the selected bit rate in the en- coder. The TP11362A meets the ITU (CCITT) G.726 recommenda- tion for 40, 32, 24, and 16 kbps ADPCM, as well as ANSI T1.301 for 32 kbps. Each channel can be operated with an independently selectable bit rate determined by QSEL1 and QSEL0 (see Table 1). TABLE 1. Bit Rate Selection QSEL1 QSEL0 ADPCM Bit Rate 0 0 32 kbps 0 1 24 kbps 1 0 16 kbps 1 1 40 kbps The ADPCM encoder converts the 64 kbps A-law or µ-law PCM input signal to a uniform PCM signal which is sub- tracted from an estimated signal obtained from an adaptive predictor. A 31-, 15-, 7-, or 4-level non-uniform quantizer is used to assign five, four, three or two binary digits, respec- tively, to the value of the difference signal for transmission. The ADPCM decoder reconstructs the original PCM signal by adding the received quantized signal to the signal estima- tion calculated by the predictor. A synchronous coding ad- justment unit prevents cumulative distortion occurring on synchronous tandem codings (ADPCM-PCM-ADPCM) un- der certain conditions. The adaptive predictor consists of two independent predictor structures. One uses a second order recursive filter which models the poles, and the other uses a sixth order non-recursive filter which models the zeros in the input sig- nal. This dual structure enables effective handling of both speech and voice band data signals. ADPCM PROCESSING ADPCM to PCM Decoding Operation When a logic “0” of TRB is latched in with the falling edge of CE, the ADPCM processor is set to the decoding mode. Data applied at the RSI input is sampled with the falling edge of ASCK into a 5-bit ADPCM serial register. Within the next cycle of CE, the decoder converts the ADPCM input data to an 8-bit companded PCM data after 123 master clocks (CLK). The 8-bit parallel PCM data is loaded into a parallel-to-serial shift register and shifted out at the RSO out- put with the rising edges of PSCK. PCM to ADPCM Encoding Operation A logic “1” of TRB at the falling edge of CE sets the ADPCM processor to the encoding mode. Data applied at the TSI in- put is sampled in an internal 8-bit PCM register with the fall- ing edge of PSCK. During the next cycle of CE, the encoder converts the companded 8-bit PCM data into a 5-, 4-, 3- or 2-bit ADPCM data, which will be shifted out during the third cycle of CE at the TSO output with the rising edges of ASCK. The TP11362A requires one master clock signal CLK. The master clock signal CLK is not required to be synchronous to the serial I/O clocks ASCK or PSCK. The serial interface uses the serial clocks ASCK and PSCK and chip enable CE for receiving and transmitting data. The data is internally synchronized to the master clock CLK. There is a lower limit of the clock frequency for CLK resulting from the number of clock cycles required for processing the data. Table 2 shows the required clock cycles per channel depending on the se- lected mode. TABLE 2. Processing Cycles Mode of Operation CLK Cycles Needed Decoder 123 Encoder 123 Initialized Channel 45 Disabled Channel 4 The sampling period (usually 125 µs for 8 kHz frame) divided by the number of CLK cycles gives the required minimum CLK period. A slightly higher CLK frequency is used in order to allow for jitter and inaccuracies in the CLK rate. As an ex- ample, for a four channel ADPCM codec, CLK frequency is 8 MHz as shown in the following calculations: t CLK = 125 µs /(8 * 123) = 127.03 ns f CLKmin = 1/tCLK = 7.872 MHz f CLKnom = 8.0 MHz The period of CE must be equal to or greater than the re- quired number of CLK cycles times the period of CLK. CE must be low for more than 4 CLK cycles. 3 www.national.com |
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