KSZ9031RNX(2012) データシートの表示(PDF) - Micrel
部品番号
コンポーネント説明
メーカー
KSZ9031RNX Datasheet PDF : 75 Pages
| |||
Micrel, Inc.
KSZ9031RNX
Analog-to-Digital Converter (ADC)
In 1000Base-T mode, the analog-to-digital converter (ADC) digitizes the incoming signal. ADC performance is essential to
the overall performance of the transceiver.
This circuit is disabled in 10Base-T/100Base-TX mode.
Timing Recovery Circuit
In 1000Base-T mode, the mixed-signal clock recovery circuit together with the digital phase-locked loop is used to recover
and track the incoming timing information from the received data. The digital phase-locked loop has very low long-term
jitter to maximize the signal-to-noise ratio of the receive signal.
The 1000Base-T slave PHY must transmit the exact receive clock frequency recovered from the received data back to the
1000Base-T master PHY. Otherwise, the master and slave will not be synchronized after long transmission. This also
helps to facilitate echo cancellation and NEXT removal.
Adaptive Equalizer
In 1000Base-T mode, the adaptive equalizer provides the following functions:
• Detection for partial response signaling
• Removal of NEXT and ECHO noise
• Channel equalization
Signal quality is degraded by residual echo that is not removed by the analog hybrid because of impedance mismatch.
The KSZ9031RNX uses a digital echo canceller to further reduce echo components on the receive signal.
In 1000Base-T mode, data transmission and reception occurs simultaneously on all four pairs of wires (four channels).
This results in high-frequency cross-talk coming from adjacent wires. The KSZ9031RNX uses three NEXT cancellers on
each receive channel to minimize the cross-talk induced by the other three channels.
In 10Base-T/100Base-TX mode, the adaptive equalizer needs only to remove the inter-symbol interference and recover
the channel loss from the incoming data.
Trellis Encoder and Decoder
In 1000Base-T mode, the transmitted 8-bit data is scrambled into 9-bit symbols and further encoded into 4D-PAM5
symbols. The initial scrambler seed is determined by the specific PHY address to reduce EMI when more than one
KSZ9031RNX is used on the same board. On the receiving side, the idle stream is examined first. The scrambler seed,
pair skew, pair order, and polarity must be resolved through the logic. The incoming 4D-PAM5 data is then converted into
9-bit symbols and de-scrambled into 8-bit data.
Functional Description: 10/100/1000 Transceiver Features
Auto MDI/MDI-X
The Automatic MDI/MDI-X feature eliminates the need to determine whether to use a straight cable or a crossover cable
between the KSZ9031RNX and its link partner. This auto-sense function detects the MDI/MDI-X pair mapping from the
link partner, and assigns the MDI/MDI-X pair mapping of the KSZ9031RNX accordingly.
Table 1 shows the KSZ9031RNX 10/100/1000 pin configuration assignments for MDI/MDI-X pin mapping.
Pin (RJ-45 pair)
TXRXP/M_A (1,2)
TXRXP/M_B (3,6)
TXRXP/M_C (4,5)
TXRXP/M_D (7,8)
1000Base-T
A+/–
B+/–
C+/–
D+/–
MDI
100Base-TX
TX+/–
RX+/–
Not used
Not used
10Base-T
TX+/–
RX+/–
Not used
Not used
1000Base-T
B+/–
A+/–
D+/–
C+/–
MDI-X
100Base-TX
RX+/–
TX+/–
Not used
Not used
10Base-T
RX+/–
TX+/–
Not used
Not used
Table 1. MDI/MDI-X Pin Mapping
October 2012
19
M9999-103112-1.0
Share Link: 