Robust serial advanced technology attachment (SATA) cable connector

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to connectors. More particularly, the present invention relates to a robust cable connector configured in accordance with a Serial Advanced Technology Attachment (SATA) standard.

2. Description of the Prior Art and Related Information

Today, computers are routinely used both at work and in the home. Computers advantageously enable file sharing, the creation of electronic documents, the use of application specific software, and electronic commerce through the Internet and other computer networks. Typically, each computer has a storage peripheral. For example, the most common type of storage peripheral is a rotating media storage device (RMSD), such as a disk drive (e.g. a hard disk drive). However, other types of storage peripherals such as solid-state disk drive emulators utilizing flash memory are becoming increasingly common.

Disk drives are typically connected to a host computer through a host interface connector for the transfer of commands, status and data. The host computer accesses the disk drive and reads data from the disk drive and/or saves data to the disk drive. The disk drive is typically connected to the host computer via a cable and a cable connector that connects to a PCB connector of the disk drive. For compatibility, the connectors and interface protocol are standardized. Accordingly, the cable, cable connector, and PCB connector must comply with the same interface standard. There are several disk drive interface standards, e.g., Advanced Technology Attachment (ATA) and Small Computer System Interface (SCSI) that have become common in the last decade.

However, disk drives are now being designed to comply with a newer standard, generally referred to as the Serial Advanced Technology Attachment (SATA) standard, which is the standard presently favored for newer computers. The SATA standard is being promulgated by the Serial ATA Working Group and is specifically referred to as the Serial ATA: High Speed Serialized AT Attachment specification or Serial ATA standard 1.0. The SATA specification defines various general standards for SATA compliant cable connectors, SATA compliant cables, and SATA compliant PCB connectors that mount to a printed circuit board (PCB).

The SATA PCB connector defined in the SATA specification basically specifies an insulated housing, a first blade connector for supporting an electrical contact arrangement configured for data signals, a second blade connector for supporting an electrical contact arrangement configured for power signals, and two board locks fixed to the housing for attaching the PCB connector to a PCB. Further, the SATA PCB connector defined in the SATA specification sets forth that the housing includes a pair of opposed guide slots in each one of two opposite side walls of the housing that define a cable connector receiving area The pair of opposed guide slots aid in guiding cable and back-plane connectors to mate with a blade connector.

Unfortunately, the blade connectors specified by the SATA standard are prone to mechanical failure when utilizing presently manufactured SATA compliant cable connectors and PCB connectors. Oftentimes, the blade connector of a SATA PCB connector breaks when a SATA cable connector is mated to it. This is because mating SATA cable connectors are not suitably constrained by the housing of the SATA PCB connector. Furthermore, the respective electrical contact arrangements for power and data signals, as specified by the SATA standard, may not adequately ensure that electrostatic discharge (ESD) will be consistently discharged with the first mate ground contact.

SUMMARY OF THE INVENTION

The present invention relates to a robust cable connector configured in accordance with a Serial Advanced Technology Attachment (SATA) standard.

In one aspect, the invention may be regarded as a cable connector having a first electrical contact arrangement in accordance with a SATA standard and configured to mate with a first blade connector having a second electrical contact arrangement also in accordance with the SATA standard. The cable connector includes a first blade-receiving portion for enclosing the first electrical contact arrangement, a housing for supporting the first blade-receiving portion and the first electrical contact arrangement, and at least one guide arm being integrally formed with the housing. The housing has a cable entrance end and a mating end. Further, the guide arm projects from the mating end of the housing and is disposed outside of and is separate from the first blade-receiving portion.

In one embodiment, the first electrical contact arrangement may be configured for data signals in accordance with the SATA standard. Alternatively, in another embodiment, the first electrical contact arrangement may be configured for power signals in accordance with the SATA standard. In one embodiment, the first blade-receiving portion may be integrally molded with the housing.

In a more detailed embodiment, the guide arm may include a conductive contact. For example, the conductive contact may comprise a grounding clip. In other embodiments, the housing and the guide arm may be made from a conductive plastic material. Further, the guide arm may be approximately rectangularly shaped. Additionally, the SATA standard may be a Serial Attached Small Computer System Interface (SAS) standard.

In another aspect, the invention may be regarded as a cable connector having a first electrical contact arrangement in accordance with a SATA standard and configured to mate with a first blade connector having a second electrical contact arrangement also in accordance with the SATA standard. The cable connector includes a first blade-receiving portion for enclosing the first electrical contact arrangement, a housing for supporting the first blade-receiving portion and the first electrical contact arrangement, and a pair of laterally-opposed guide arms being integrally formed with the housing. The housing has a cable entrance end and a mating end. Further, the guide arms project from the mating end of the housing and are disposed outside of and are separate from the first blade-receiving portion.

In one embodiment, the first electrical contact arrangement may be configured for data signals in accordance with the SATA standard. Alternatively, in another embodiment, the first electrical contact arrangement may be configured for power signals in accordance with the SATA standard. In one embodiment, the first blade-receiving portion may be integrally molded with the housing.

In a more detailed embodiment, the housing may include a connector-support gap for receiving a second blade-receiving portion. The second blade-receiving portion may support a third electrical contact arrangement to mate with a second blade connector having a fourth electrical contact arrangement in accordance with the SATA standard. For example, the first electrical contact arrangement may be configured for data signals in accordance with the SATA standard and the third electrical contact arrangement may be configured for power signals in accordance with the SATA standard. In one embodiment, both the first and second blade-receiving portions may be integrally molded with the housing.

In yet a more detailed embodiment, at least one of the guide arms may include a conductive contact. For example, the conductive contact may comprise a grounding clip. In other embodiments, the housing and the guide arms may be made from a conductive plastic material. Further, the guide arms may be approximately rectangularly shaped or approximately oval shaped. Also, the guide arms may be differently sized. Additionally, the SATA standard may be a Serial Attached Small Computer System Interface (SAS) standard.

In a further aspect, the invention may be regarded as a cable connector having a first electrical contact arrangement in accordance with a SATA standard and configured to mate with a first blade connector having a second electrical contact arrangement also in accordance with the SATA standard, in which, the cable connector includes a first blade-receiving portion for enclosing the first electrical contact arrangement, a housing for supporting the first blade-receiving portion and the first electrical contact arrangement, a connector-support gap formed in the housing for receiving a second blade-receiving portion, and a pair of laterally-opposed guide arms being integrally formed with the housing. The housing has a cable entrance end and a mating end. Further, the guide arms project from the mating end of the housing and are disposed outside of and are separate from the first blade-receiving portion.

In one embodiment, the first electrical contact arrangement may be configured for data signals in accordance with the SATA standard. Alternatively, in another embodiment, the first electrical contact arrangement may be configured for power signals in accordance with the SATA standard. Further, in one embodiment, the first blade-receiving portion may be integrally molded with the housing.

In yet a more detailed embodiment, at least one of the guide arms may include a conductive contact. For example, the conductive contact may comprise a grounding clip. In other embodiments, the housing and the guide arms may be made from a conductive plastic material. Further, the guide arms may be approximately rectangularly shaped or approximately oval shaped. Also, the guide arms may be differently sized. Additionally, the SATA standard may be a Serial Attached Small Computer System Interface (SAS) standard.

In an additional aspect, the invention may be regarded as a cable assembly having a cable connector including a first electrical contact arrangement in accordance with a SATA standard and configured to mate with a second electrical contact arrangement in accordance with the SATA standard. The cable assembly includes a first blade-receiving portion for enclosing the first electrical contact arrangement, a housing for supporting the first blade-receiving portion and the first electrical contact arrangement, at least one guide arm being integrally formed with the housing, and a first shielded cable having a first plurality of conductors configured in accordance with the SATA standard and connected to the first electrical contact arrangement. The housing has a cable entrance and a mating end. The guide arm projects from the mating end of the housing and is disposed outside of and is separate from the blade-receiving portion.

In one embodiment, the first electrical contact arrangement and the connected first plurality of conductors may be configured for data signals in accordance with the SATA standard. Alternatively, in another embodiment, the first electrical contact arrangement and the connected first plurality of conductors may be configured for power signals in accordance with the SATA standard. In one embodiment, the first blade-receiving portion may be integrally molded with the housing.

In a more detailed embodiment, the guide arm may include a conductive contact coupled to a conductor of the first shielded cable. For example, the conductive contact may comprise a grounding clip. In other embodiments, the housing and the guide arm may be made from a conductive plastic material. Further, the guide arm may be approximately rectangularly shaped. Additionally, the SATA standard may be a Serial Attached Small Computer System Interface (SAS) standard.

In yet another aspect, the invention may be regarded as a cable assembly having a cable connector including a first electrical contact arrangement in accordance with a SATA standard and configured to mate with a second electrical contact arrangement in accordance with the SATA standard. The cable assembly includes a first blade-receiving portion for enclosing the first electrical contact arrangement, a housing for supporting the first blade-receiving portion and the first electrical contact arrangement, a pair of laterally-opposed guide arms being integrally formed with the housing, and a first shielded cable having a first plurality of conductors configured in accordance with the SATA standard and connected to the first electrical contact arrangement. The housing has a cable entrance and a mating end. The guide arms project from the mating end of the housing and are disposed outside of and are separate from the blade-receiving portion.

In one embodiment, the first electrical contact arrangement and the connected first plurality of conductors may be configured for data signals in accordance with the SATA standard. Alternatively, in another embodiment, the first electrical contact arrangement and the connected first plurality of conductors may be configured for power signals in accordance with the SATA standard. In one embodiment, the first blade-receiving portion may be integrally molded with the housing.

In a more detailed embodiment, the housing may include a connector-support gap for receiving a second blade-receiving portion. The second blade-receiving portion may support a third electrical contact arrangement to mate with a second blade connector having a fourth electrical contact arrangement in accordance with the SATA standard. Further, a second shielded cable having a second plurality of conductors in accordance with the SATA standard may be connected to the third electrical contact arrangement of the second blade-receiving portion. For example, the first electrical contact arrangement and the first plurality of conductors of the first shielded cable may be configured for data signals in accordance with the SATA standard and the third electrical contact arrangement and the second plurality of conductors of the second shielded cable may be configured for power signals in accordance with the SATA standard. In one embodiment, both the first and second blade-receiving portions may be integrally molded with the housing.

In yet a more detailed embodiment, at least one of the guide arms may include a conductive contact coupled to a conductor of the first shielded cable. For example, the conductive contact may comprise a grounding clip. In one embodiment, each guide arm includes a conductive contact wherein one of the conductive contacts is coupled to a ground conductor of the first plurality of conductors of the first shielded cable and the other one of the conductive contacts is coupled to a ground conductor of the second plurality of conductors of the second shielded cable. In other embodiments, the housing and the guide arms may be made from a conductive plastic material. Further, the guide arms may be approximately rectangularly shaped or approximately oval shaped. Also, the guide arms may be differently sized. Additionally, the SATA standard may be a Serial Attached Small Computer System Interface (SAS) standard.

The foregoing and other features of the invention are described in detail below and set forth in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A

shows a block diagram of a system including a host computer connected to a storage peripheral, in which embodiments of the invention may be practiced.

FIG. 1B

shows a block diagram of a system including a host computer connected to a disk drive, in which embodiments of the invention may be practiced.

FIG. 2

shows a perspective view of a cable connector for mating to a PCB connector connected to a PCB, according to one embodiment of the invention.

FIG. 3A

shows a perspective view of a cable connector having a first blade-receiving portion that includes a first electrical contact arrangement configured for data signals in accordance with a SATA standard, according to one embodiment of the invention.

FIG. 3B

shows a perspective view of a cable connector having a first blade-receiving portion configured for data signals in accordance with the SATA standard and a second blade-receiving portion configured for power signals in accordance with the SATA standard, according to one embodiment of the invention.

FIG. 3C

shows a perspective view of a cable connector having guide arms that are approximately oval shaped, according to one embodiment of the invention.

FIG. 4A

shows a perspective view of another embodiment of a cable connector configured for power signals in accordance with the SATA standard, according to one embodiment of the invention.

FIG. 4B

shows a perspective view of another embodiment of a cable connector configured for data signals in accordance with the SATA standard, according to one embodiment of the invention.

FIG. 4C

shows a perspective view of another embodiment of a cable connector configured for data signals in accordance with the SATA standard, according to one embodiment of the invention.

FIG. 4D

shows a perspective view of another embodiment of a cable connector configured for power signals in accordance with the SATA standard, according to one embodiment of the invention.

FIG. 4E

shows a perspective view of another embodiment of a cable connector configured for power signals in accordance with the SATA standard, according to one embodiment of the invention.

FIG. 4F

shows a perspective view of another embodiment of a cable connector configured for both data and power signals in accordance with the SATA standard, according to one embodiment of the invention.

FIG. 5A

shows a more detailed perspective view of the PCB connector of

FIG. 2

, according to one embodiment of the invention.

FIG. 5B

shows a perspective view of a PCB connector having guide arm receiving cavities that are approximately oval shaped, according to one embodiment of the invention.

FIG. 5C

shows a perspective view of another embodiment of the PCB connector, according to one embodiment of the invention.

FIG. 6A

is a schematic diagram showing a pre-grounding configuration wherein both the data blade-receiving portion and the power blade-receiving portion of the cable connector are configured for pre-grounding to the PCB connector, according to one embodiment of the invention.

FIG. 6B

is a schematic diagram showing a pre-grounding configuration wherein the data blade-receiving portion is not present and the power blade-receiving portion of the cable connector is configured for pre-grounding to the PCB connector, according to one embodiment of the invention.

FIG. 6C

is a schematic diagram showing a pre-grounding configuration wherein the power blade-receiving portion is not present and the data blade-receiving portion of the cable connector is configured for pre-grounding to the PCB connector, according to one embodiment of the invention.

FIG. 6D

shows a layout of the data and power signal contacts of the data and power blade connectors of the PCB connector onto the PCB and further shows grounding tabs of the guide arm receiving cavities coupled to ground on the PCB, according to one embodiment of the invention.

DETAILED DESCRIPTION

With reference to

FIG. 1A

,

FIG. 1A

shows a block diagram of a system including a host computer

12

connected to a storage peripheral

8

, in which embodiments of the invention may be practiced. The storage peripheral

8

comprises a controller

26

having a Serial ATA (SATA) interface (not shown) connected to a SATA PCB connector

24

. The storage peripheral

8

further includes a semiconductor memory

28

for data storage and retrieval. The controller

26

, semiconductor memory

28

, and SATA PCB connector

24

are preferably mounted on a printed circuit board (PCB)

13

. The storage peripheral

8

is connectable to a host computer

12

for receiving commands and data over a SATA cable

70

having a SATA cable connector

22

.

In one embodiment, storage peripheral

8

may emulate a disk drive while communicating with the host computer

12

using a SATA protocol. Semiconductor memory

28

may be a Flash memory system for providing non-volatile storage. In another embodiment, semiconductor memory

28

may be a large DRAM array suitable for caching data in a high performance system.

With reference to

FIG. 1B

,

FIG. 1B

shows a block diagram of a system including a host computer

12

′ connected to a disk drive

10

, in which embodiments of the invention may be practiced. In this embodiment, the disk drive

10

acts as the storage peripheral. The disk drive

10

includes a head disk assembly (HDA)

17

having a disk

18

and a transducer head

20

actuated radially over the disk. The disk drive

10

further includes a disk control system

25

, which may include a SATA interface (not shown), and a serial ATA (SATA) PCB connector

24

′. The disk control system

25

responds to disk-drive commands and accesses data storage locations on the disk

18

through the transducer head

20

. The SATA PCB connector

24

′ couples the disk control system

25

to the host computer

12

′ when the disk drive

10

is connected to the host computer

12

′ via the SATA cable

70

′ and the SATA cable connector

22

′.

The HDA

17

of disk drive

10

further includes a spindle motor

52

for rotating the disk

18

and a voice coil motor (VCM)

54

for actuating the transducer head

20

radially over the disk

18

. A servo controller

56

generates the appropriate control signals applied to the spindle motor

52

and the VCM

54

in response to commands received from the disk control system

25

. During a write operation the disk control system

25

transmits user data received from the host computer

12

′ to a read/write channel

58

. The read/write channel

58

performs appropriate encoding of the user data to generate write data

60

written to the disk

18

. The write data

60

modulates the operation of a preamp

62

to generate a write signal

64

, applied to the head

20

in order to write magnetic transitions onto the surface of the disk

18

. During a read operation, the head

20

detects the magnetic transitions representing the recorded data to generate a read signal

66

i

which is amplified by the preamp

62

to generate a read signal

68

applied to the read/write channel

58

. The read/write channel

58

demodulates the read signal

68

into user data transmitted to the host computer

12

′ via disk control system

25

after correcting errors.

The disk drive

10

communicates with the host computer

12

′ over a SATA cable

70

′ that includes a SATA cable connector

22

′ connected to the SATA PCB connector

24

′ using a communication protocol defined by an industry standard such as the Serial ATA standard 1.0. In another embodiment, the disk drive may communicate with the host computer using an industry standard known as Serial Attached SCSI (SAS), which contemplates using cabling and circuitry originally defined in the SATA standard.

The disk

18

, spindle motor

52

, VCM

54

, preamp

62

, and related hardware may be integrated into the HDA

17

. The disk control system

25

, SATA PCB connector

24

′, semiconductor memory

28

′, servo controller

56

, read/write channel

58

, and related electronics may be mounted on a printed circuit board (PCB)

13

′. The disk control system

25

generally includes circuitry and processors that control the HDA

17

and that provide an intelligent control interface between the host computer

12

′ and the HDA for execution of disk-drive commands. The disk control system

25

may have an internal microprocessor and nonvolatile memory for implementing the techniques of the invention. The semiconductor memory

28

′ may have nonvolatile memory and volatile random access memory (RAM).

The following discussion will describe embodiments of the invention related to SATA cable connectors

22

,

22

′, SATA PCB connectors

24

,

24

′ connected to PCBs

13

,

13

′, SATA cables

70

,

70

′, etc. It should be appreciated that the following description of SATA cable connectors, SATA PCB connectors, and SATA cables is applicable to either of the system environments of

FIGS. 1A and 1B

for a storage peripheral

8

or a disk drive

10

, respectively, both of which have been previously described in detail, as well as other types of system environments. Moreover, it should be appreciated that embodiments of the SATA PCB connectors

24

can similarly be connected to PCBs associated with a host computer or back-plane such that SATA cable connectors

22

can be connected to these PCB connectors and an interface can be provided at the host computer or back-plane end.

With reference now to

FIGS. 2 and 3A

,

FIG. 2

shows a perspective view of a cable connector

22

for mating to a PCB connector

24

connected to a PCB

13

and

FIG. 3A

shows another perspective view of the cable connector

22

having a first blade-receiving portion

212

that includes a first electrical contact arrangement

213

configured in accordance with a SATA standard. The first electrical contact arrangement

213

of the first blade-receiving portion

212

is configured to mate with a first blade connector

206

of the PCB connector having a second electrical contact arrangement (not shown) also in accordance with the SATA standard.

Particularly, in one embodiment, the cable connector

22

includes a first blade-receiving portion

212

for enclosing the first electrical contact arrangement

213

, a housing

210

for supporting the first blade-receiving portion

212

, and at least one guide arm

220

that is integrally formed with the housing. In one embodiment, a pair of laterally-opposed guide arms

220

are integrally formed with the housing. Also, in one embodiment, a connector-support gap

230

is formed in the housing

210

for receiving a second blade-receiving portion

225

. Further, the housing

210

has a cable entrance end

214

and a mating end

216

.

At least one guide arm

220

projects from the mating end

216

of the housing

210

and is disposed outside of and is separate from the first blade-receiving portion

212

. Further, in one embodiment, a pair of laterally-opposed guide arms

220

project from the mating end

216

of the housing

210

and are disposed outside of and are separate from the first blade-receiving portion

212

.

Also, in one embodiment, a first shielded cable

272

having a first plurality of conductors configured in accordance with the SATA standard may be connected to the first blade-receiving portion

212

. The first plurality of conductors are connected to the first electrical contact arrangement of the first blade-receiving portion

212

. The combination of the cable connector

22

including the first blade-receiving portion

212

and the first shielded cable

272

connected thereto may be referred to as cable assembly

23

.

The housing

210

of the cable connector

22

is approximately U-shaped and has the connector-support gap

230

formed therein. The pair of laterally-opposed guide arms

220

project from the mating end

216

of the housing

210

and are disposed outside of and are separate from the first blade-receiving portion

212

and the connector-support gap

230

. The housing

210

includes a guide slot

217

in one of two opposite sidewalls

218

of the housing that aids in defining the connector-support gap

230

. Further, the top portion

219

of the housing may optionally have rectangular recesses

221

.

In one embodiment, the first electrical contact arrangement

213

of the first blade-receiving portion

212

is configured for data signals in accordance with the SATA standard and is particularly configured to mate with the first blade connector

206

of the PCB connector

24

having a second electrical contact arrangement (not shown) also configured for data signals in accordance with the SATA standard. Further, the first shielded cable

272

having a plurality of conductors is configured for data signals in accordance with the SATA standard and is coupled to the data blade-receiving portion

212

. The plurality of conductors of the first shielded cable

272

are connected to the data electrical contact arrangement

213

of the data blade-receiving portion

212

.

The data blade-receiving portion

212

includes a generally oblong rectangular housing

223

for enclosing the data electrical contact arrangement

213

configured in accordance with the SATA standard. At one end, the data blade-receiving portion

212

includes an L-shaped opening

225

for receipt of the corresponding L-shaped data blade connector

206

of the PCB connector

24

which has a mating data electrical contact arrangement configured in accordance with the SATA standard such that the data blade connector

206

properly mates with the data electrical contact arrangement

213

of the data blade-receiving portion

212

. At the other end, the data blade-receiving portion

212

receives the shielded cable

272

having a plurality of conductors configured for data signals in accordance with the SATA standard and the plurality of conductors are connected to the data electrical contact arrangement

213

inside the housing

223

of the data blade-receiving portion

212

.

Further, the data blade-receiving portion

212

includes a side guide rail

227

to mate with the PCB connector

24

, as will be discussed in detail later. Also, the data blade-receiving portion

212

further includes a side guide slot

229

for receipt of a guide rail

236

of the second blade-receiving portion

225

, as will be discussed. The data blade-receiving portion

212

may be integrally molded with the housing

210

.

It should be appreciated that, in an alternative embodiment, the first electrical contact arrangement of the first blade-receiving portion may be configured for power signals in accordance with the SATA standard and would instead mate with a blade connector of the PCB connector likewise having an electrical contact arrangement configured for power signals in accordance with the SATA standard. Further, the first shielded cable having a plurality of conductors would be configured for power signals in accordance with the SATA standard. The plurality of conductors of the first shielded cable would connected to the power electrical contact arrangement of the power blade-receiving portion.

An example of this can be seen with reference to FIG.

4

A.

FIG. 4A

shows an alternative embodiment of a cable connector

422

including a first blade-receiving portion

412

having a first electrical contact arrangement

413

configured for power signals in accordance with the SATA standard and which is configured to mate with a blade connector of a PCB connector likewise having an electrical contact arrangement configured for power signals in accordance with the SATA standard. Further, the first shielded cable

474

has a plurality of conductors configured for power signals in accordance with the SATA standard. The plurality of conductors of the first shielded cable

474

are connected to the power electrical contact arrangement

413

of the power blade-receiving portion

412

. The combination of the power cable connector

422

including the first blade-receiving portion

412

having the first electrical contact arrangement

413

configured for power signals and the first shielded cable

474

configured for power signals connected thereto may be referred to as cable assembly

423

. The blade-receiving portion configured for power signals in accordance with the SATA standard will be discussed in detail later.

Continuing with reference to

FIG. 2

as well as with reference to

FIG. 3B

, which shows a second blade-receiving portion

225

, the use of a second blade-receiving portion will now be described. As previously discussed, a connector-support gap

230

is formed in the housing

210

for receiving a second blade-receiving portion

225

. The second blade-receiving portion

225

supports a third electrical contact arrangement

232

to mate with a second blade connector

228

having a fourth electrical contact arrangement (not shown) in accordance with the SATA standard.

In one embodiment, the third electrical contact arrangement

232

is configured for power signals in accordance with the SATA standard and is configured to mate with the second blade connector

228

of the PCB connector

24

having a fourth electrical contact arrangement (not shown) also configured for power signals in accordance with the SATA standard. Particularly, in this embodiment, the cable connector

22

includes a second blade-receiving portion

225

for enclosing the power electrical contact arrangement

232

. Further, a shielded cable

274

having a plurality of conductors configured for power signals in accordance with the SATA standard is coupled to the power blade-receiving portion

225

and the plurality of conductors are connected to the power electrical contact arrangement

232

of the power blade-receiving portion

225

inside the power blade-receiving portion. In this embodiment, the combination of the cable connector

22

including the data and power blade-receiving portions

212

,

225

and their respective first and second shielded cables

272

,

274

(i.e. data and power shielded cables) connected thereto, may be referred to as cable assembly

23

.

For example,.in this embodiment, as shown in

FIGS. 2 and 3B

, the first electrical contact arrangement

213

of the first blade-receiving portion

212

and the first shielded cable

272

may be configured for data signals in accordance with the SATA standard to mate with the first blade connector

206

of the PCB connector

24

having a second electrical contact arrangement similarly configured for data signals in accordance with the SATA standard and the third electrical contact arrangement

232

of the second blade-receiving portion

225

and the second shielded cable

274

may be configured for power signals in accordance with the SATA standard to mate with the second blade connector

228

of the PCB connector

24

having a fourth electrical contact arrangement similarly configured for power signals in accordance with the SATA standard. Accordingly, the data blade-receiving portion

212

mates with the data blade connector

206

of the PCB connector

24

and the power blade-receiving portion

225

mates with the power blade connector

228

of the PCB connector

24

, respectively.

Looking particularly at the power blade-receiving portion

225

, the power blade-receiving portion

225

includes a generally rectangular housing

233

for enclosing the power electrical contact arrangement

232

configured in accordance with the SATA standard. At one end, the power blade-receiving portion

225

includes an L-shaped opening

235

for receipt of the corresponding L-shaped power blade connector

228

of the PCB connector

24

, which has a mating power electrical contact arrangement configured in accordance with the SATA standard, such that the power blade connector

228

of the PCB connector

24

properly mates with the power electrical contact arrangement

232

of the power blade-receiving portion

225

. At the other end, the power blade-receiving portion

225

receives shielded cable

274

having a plurality of conductors configured for power signals in accordance with the SATA standard and the plurality of conductors are connected to the power electrical contact arrangement

232

inside the housing

233

of the power blade-receiving portion

225

.

Further, the power blade-receiving portion

225

includes a pair of side guide rails. A first guide rail

234

mates with the opposed guide slot

217

of the housing

210

such that the power blade-receiving portion

225

interlocks with the housing

210

of the cable connector

22

and a second slender rectangular guide rail

236

mates with the side guide slot

229

of the data blade-receiving portion

212

and interlocks with the data blade-receiving portion. In this way, by the power blade-receiving portion

225

interlocking with the housing

210

and the data blade-receiving portion

212

, an integral cable connector

22

is formed. Alternatively, in another embodiment, the data blade-receiving portion

212

and the power blade-receiving portion

225

may be integrally molded with the housing

210

.

Continuing with reference to

FIGS. 2 and 3B

, the pair of laterally-opposed guide arms

220

will now be discussed. As previously described, the guide arms

220

project from the mating end

216

of the housing

210

of the cable connector

22

and are disposed outside of and are separate from the first blade-receiving portion

212

and the connector-support gap

230

. In one embodiment, the guide arms

220

are approximately rectangularly shaped as particularly shown in FIG.

3

B. Further, as shown in

FIG. 3B

, the guide arms

220

may be differently sized.

In one embodiment each of the guide arms

220

may include a conductive contact

237

such as a grounding clip. As will be described in more detail later, the conductive contacts may provide pre-grounding functionality for one of the data or power blade-receiving portions or both. For example, one of the conductive contacts

237

of a one of the guide arms may be coupled to a ground conductor of the first shielded cable

272

(e.g. configured for data signals) and the other conductive contact

237

of the other guide arm may be coupled to a ground conductor of the second shielded cable

274

(e.g. configured for power signals), as will be discussed. Various other grounding configurations for pre-grounding and the dissipation of electro-static discharge (ESD) will also be discussed.

Also, in one embodiment, the housing

210

and the guide arms

220

may be made from a conductive plastic material such that the cable connector

22

is conductive. For example, the plastic material may include a conductive filler material. This may be referred to as the conductive cable connector embodiment.

With reference now to

FIG. 3C

, in another embodiment, the guide arms

221

may be approximately oval shaped. Again, as previously described, the guide arms

221

may be differently sized. Further, although not shown in

FIG. 3C

, each oval shaped guide arm

221

may also include a conductive contact such as a grounding clip.

Various other alternative embodiments of the previously described cable connectors are also possible. For example, as shown in

FIG. 4B

, in one embodiment, a cable connector

448

utilized only for data signal connection is shown. The data cable connector

448

may include a housing

452

for supporting a data blade-receiving portion

212

having an electrical contact arrangement

213

configured for data signals in accordance with the SATA standard. The data blade-receiving portion

212

may be integrally molded with the housing

452

. Further, in this embodiment, the data cable connector

448

only includes one guide arm

220

. The guide arm

220

is integrally formed with the housing

452

and projects from the mating end of the housing and is disposed outside of and is separate from the data blade-receiving portion

212

. The guide arm includes a conductive contact

237

, such as a grounding clip. Alternatively, as previously discussed, the housing

452

and the guide arm

220

may be made from a conductive plastic material.

The data electrical contact arrangement

213

of the data blade-receiving portion

212

is configured to mate with the data blade connector

206

of the PCB connector

24

having an electrical contact arrangement also configured for data signals in accordance with the SATA standard. Further, a shielded cable

272

having a plurality of conductors configured for data signals in accordance with the SATA standard is coupled to the data blade-receiving portion

212

and the plurality of conductors are connected to the data electrical contact arrangement

213

of the data blade-receiving portion

212

inside the data blade-receiving portion. As previously discussed, the conductive contact

237

of the guide arm

220

may be coupled to a ground conductor of the shielded data cable

272

(e.g. configured for data signals) for pre-grounding. The rectangular guide arm

220

is suitably formed for receipt by a guide arm receiving cavity of the PCB connector

24

, as will be discussed. Also, the SATA standard utilized may be a SAS standard.

Further, the housing

452

may include a side guide slot

454

for mating with a rectangular guide rail of another separate power cable connector, as will be discussed.

Also, with reference to

FIG. 4C

, an alternative embodiment of the data cable connector

448

is shown. In this embodiment, the data cable connector

448

includes a second guide arm

458

that is shaped as an elongated tongue. The second elongated tongue guide arm

458

is suitably formed for receipt by a guide arm receiving cavity of the PCB connector

24

that is shaped as elongated slot, as will be discussed.

Another alternative embodiment of the previously described cable connectors is shown in FIG.

4

D.

FIG. 4D

shows a cable connector

460

that is utilized only for power signal connection. The power cable connector

460

may include a housing

462

for supporting a power blade-receiving portion

225

having an electrical contact arrangement

232

configured for power signals in accordance with the SATA standard. The power blade-receiving portion

225

may be integrally molded with the housing

462

. Further, in this embodiment, the power cable connector

460

only includes one guide arm

220

. The guide arm

220

is integrally formed with-the housing

462

and projects from the mating end of the housing and is disposed outside of and is separate from the power blade-receiving portion

225

. The guide arm includes a conductive contact

237

, such as a grounding clip. Alternatively, as previously discussed, the housing

462

and the guide arm

220

may be made from a conductive plastic material.

The power electrical contact arrangement

232

of the power blade-receiving portion

225

is configured to mate with the power blade connector

228

of the PCB connector

24

having an electrical contact arrangement also configured for power signals in accordance with the SATA standard. Further, a shielded cable

274

having a plurality of conductors configured for power signals in accordance with the SATA standard is coupled to the power blade-receiving portion

225

and the plurality of conductors are connected to the power electrical contact arrangement

232

of the power blade-receiving portion

225

inside the power blade-receiving portion. As previously discussed, the conductive contact

237

of the guide arm

220

may be coupled to a ground conductor of the shielded power cable

274

(e.g. configured for power signals) for pre-grounding. The rectangular guide arm

220

is suitably formed for receipt by a guide arm receiving cavity of the PCB connector

24

, as will be discussed. Also, the SATA standard utilized may be a SAS standard.

Further, the housing

462

may include a side guide rail

464

for mating with side guide slot

454

of the data cable connector

448

.

Also, with reference to

FIG. 4E

, an alternative embodiment of the power cable connector

460

is shown. In this embodiment, the power cable connector

460

includes a second guide arm

468

that is shaped as an elongated tongue. The second elongated tongue guide arm

468

is suitably formed for receipt by a guide arm receiving cavity of the PCB connector

24

that is shaped as elongated slot, as will be discussed.

An additional alternative embodiment of the previously described cable connectors is shown in FIG.

4

F.

FIG. 4F

shows a combined cable connector

480

that is utilized for both data and power signal connection and is a combination of the data cable connector

448

and the power cable connector

460

, previously discussed. The combined cable connector

480

may be formed by the combination of the power and data cable connectors

460

,

448

, previously discussed, by the side guide rail

464

of the power cable connector mating with the side guide slot

454

of the data cable connector

448

to form the combined cable connector

480

. Alternatively, the combined cable connector

480

may be formed by the integral molding of the previously described power and data cable connectors

460

,

448

, respectiv

The combined cable connector

480

may include a housing

482

for supporting both the data blade-receiving portion

212

having an electrical contact arrangement

213

configured for data signals in accordance with the SATA standard and a power blade-receiving portion

225

having an electrical contact arrangement

232

configured for power signals in accordance with the SATA standard. In this embodiment, a pair of laterally-opposed guide arms

220

are integrally formed with the housing

482

and project from the mating end of the housing and are disposed outside of and are separate from both the data and power blade-receiving portions

212

,

225

. The guide arms each include a conductive contact

237

, such as a grounding clip. Alternatively, as previously discussed, the housing

482

and the guide arms

220

may be made from a conductive plastic material.

The data electrical contact arrangement

213

of the data blade-receiving portion

212

is configured to mate with the data blade connector

206

of the PCB connector

24

having an electrical contact arrangement also configured for data signals in accordance with the SATA standard. Further, a shielded cable

272

having a plurality of conductors configured for data signals in accordance with the SATA standard is coupled to the data blade-receiving portion

212

and the plurality of conductors are connected to the data electrical contact arrangement

213

of the data blade-receiving portion

212

inside the data blade-receiving portion. As previously discussed, the conductive contact

237

of the guide arm

220

may be coupled to a ground conductor of the shielded data cable

272

(e.g. configured for data signals) for pre-grounding. The power electrical contact arrangement

232

of the power blade-receiving portion

225

is configured to mate with the power blade connector

228

of the PCB connector

24

having an electrical contact arrangement also configured for power signals in accordance with the SATA standard. Further, a shielded cable

274

having a plurality of conductors configured for power signals in accordance with the SATA standard is coupled to the power blade-receiving portion

225

and the plurality of conductors are connected to the power electrical contact arrangement

232

of the power blade-receiving portion

225

inside the power blade-receiving portion. As previously discussed, the conductive contact

237

of the guide arm

220

may be coupled to a ground conductor of the shielded power cable

274

(e.g. configured for power signals) for pre-grounding.

The rectangular guide arms

220

arc suitably formed for receipt by guide arm receiving cavities of the PCB connector

24

, as will be discussed. Also, the SATA standard utilized may be a SAS standard. Further, in this embodiment, the combined cable connector

480

includes a second guide arm

488

that is shaped as an elongated tongue. The second elongated tongue guide arm

488

is suitably formed for receipt by a guide arm receiving cavity of the PCB connector

24

that is shaped as elongated slot, as will be discussed.

With reference now to

FIG. 5A

in conjunction with

FIG. 2

, one embodiment of the PCB connector

24

will now be described in detail.

FIG. 5A

shows a more detailed perspective view of the PCB connector

24

of FIG.

2

. As shown in

FIG. 2

, the PCB connector

24

is mounted to a printed circuit board (PCB)

13

. Mounting brackets

280

of the PCB connector

24

support the PCB

13

and mounting posts

281

extend from the mounting brackets

280

via through-holes of the PCB creating an interference fit to secure the PCB connector

24

to the PCB

13

. Further, as will be discussed many pins of the various connectors are also fixed to the PCB

13

further securing the PCB connector

24

to the PCB

13

.

In one embodiment, the PCB connector

24

includes a housing

270

having a SATA section

265

, a legacy Integrated Drive Electronics (IDE) power section receptacle

266

, and a user section receptacle

268

. In other embodiments of the PCB connector

24

, the housing

270

of the PCB connector

24

may only include the SATA section

265

and the legacy IDE power section receptacle

266

and the user section receptacle

268

may not be present. Particularly, looking at the SATA section

265

, the PCB connector

24

includes a first blade connector

206

for supporting a first electrical contact arrangement

209

in accordance with a SATA standard, a second blade connector

228

for supporting a second electrical contact arrangement

231

in accordance with the SATA standard, and the housing

270

encloses the first and second blade connectors and the supported electrical contact arrangements. As should be appreciated, the electrical contacts of the electrical contact arrangements of the blade connectors

206

and

228

are mounted to the PCB

13

via through-holes of the PCB

13

, for example. Alternatively, other methods of mounting the electrical contacts could be used, such as surface mount technologies.

In one embodiment, the housing

270

includes a pair of opposed guide slots

271

in each one of two opposite sidewalls of the housing

270

that define a cable connector receiving area

252

around the first and second blade connectors

206

and

228

for the receipt of at least one cable connector, respectively. The cable connector receiving area

252

is in accordance with the SATA standard. In one embodiment, the first electrical contact arrangement

209

of the first L-shaped blade connector

206

is configured for data signals in accordance with the SATA standard and a second electrical contact arrangement

231

of the second L-shaped blade connector

228

is configured for power signals in accordance with the SATA standard.

However, above and beyond the cable connector receiving area

252

as defined in accordance with the SATA standard, the housing

270

of the PCB connector

24

includes at least one guide arm receiving cavity

254

that is integrally formed with the housing

270

and that is disposed outside of the cable connector receiving area

252

. In one embodiment, the housing

270

includes a pair of laterally-opposed guide arm receiving cavities

254

that are integrally formed with the housing

270

and that are disposed outside the cable connector receiving area

252

. The guide arm receiving cavities

254

are adapted for the receipt of the guide arms

220

from the mating cable connector

22

.

Further, in other embodiments, the guide arm receiving cavities

254

are adapted for the receipt of guide arms

220

from the other alternative embodiments of the mating cable connector-

22

such as power signal only cable connector

422

, data signal only cable connector

448

, power signal only cable connector

460

, and combined data and power signal cable connector

480

. In the cases of power signal only cable connector

422

and combined data and power signal cable connector

480

, these connectors both have two laterally-opposed guide arms both of which mate to the guide arm receiving cavities

254

. In the cases of the data signal only cable connector

448

and power signal only cable connector

460

, these connectors each have only one guide arm for mating with one of the respective guide arm receiving cavities

254

.

In one embodiment, the guide arm receiving cavities

254

are approximately rectangularly shaped and may be differently sized, as particularly shown in FIG.

5

A. With brief reference to

FIG. 5B

, in another embodiment, the guide arm receiving cavities

354

may be approximately oval shaped and may also be differently sized. Further with brief reference to

FIG. 5C

, the housing

270

of the PCB connector

24

may further have an elongated slot

292

for the receipt of the second guide arms

458

,

468

, and

488

of the data signal only cable connector

448

, the power signal only cable connector

460

, and the combined data and power signal cable connector

480

, respectively, all of which are shaped as elongated tongues, as previously discussed.

Returning to

FIGS. 2 and 5A

, the housing

270

further includes substantially thickened strengthening walls

260

disposed between the cable connector receiving area

252

and the guide arm receiving cavities

254

making the PCB connector

24

very robust.

Accordingly, above and beyond presently manufactured cable connectors that mate to the SATA standards defined cable connector receiving area of presently manufactured PCB connectors, embodiments of the present invention relate to a more robust SATA compliant cable connector

22

and SATA compliant PCB connector

24

that avoid many of the breakage problems associated with these present devices. This further applies to the other disclosed alternative embodiments of cable connector

22

such as power signal only cable connector

422

, data signal only cable connector

448

, power signal only cable connector

460

, and combined data and power signal cable connector

480

. With the embodiments of present invention, one or both of the data blade-receiving portion

212

and/or the power blade-receiving portion

225

mate with their respective data blade connector

206

and/or power blade connector

228

of the SATA defined cable connector receiving area

252

, in which one or both of guide rails

227

,

234

of the data blade-receiving portion

212

and/or the power blade-receiving portion

225

mate with one or both of the guide slots

271

of the cable connector receiving area, respectively.

More particularly, according to embodiments of the invention, the housing

210

of the cable connector

22

rigidly contains one or both of the data blade-receiving portion

212

and/or the power blade-receiving portion

225

, and when the cable connector

22

is mated to the PCB connector

24

, the pair of laterally-opposed guide arms

220

of the cable connector

22

mate with the pair of laterally-opposed guide arm cavities

254

of the PCB connector

24

such that the blade-receiving portions

212

,

225

of the cable connector mate with the blade connectors

206

,

228

of the PCB connector in an aligned and firm manner such that the common problems associated with the breakage of the blade connectors is avoided. This is further applicable to the other disclosed alternative embodiments of cable connector

22

such as power signal only cable connector

422

, data signal only cable connector

448

, power signal only cable connector

460

, and combined data and power signal cable connector

480

. However, in the case of data signal only cable connector

448

and power signal only cable connector

460

only one guide arm mates with a respective guide arm receiving cavity.

Thus, the guide arms

220

mating with the guide arm receiving cavities

254

align the blade-receiving portions

212

,

225

of the various embodiments of the disclosed cable connectors with the blade connectors

206

,

228

of the PCB connector

24

. Moreover, much of the forces associated with the blade-receiving portions mating to the blade connectors arc transferred to the guide arms

220

, the guide arm receiving cavities

254

, and the substantially thickened strengthening walls

260

of the strengthened housing

270

of the PCB connector

24

. This further reduces the forces applied to the blade connectors to further avoid breakage.

Also, the housing

270

of the PCB connector

24

may further include a legacy Integrated Drive Electronics (IDE) power section receptacle

266

, and a user section receptacle

268

. The legacy IDE power section receptacle

266

includes various legacy pins

267

, such as 12 V and 5 V power pins and associated ground pins that are connected to the PCB

13

, and that can be used for powering a storage peripheral, such as a disk drive, instead of utilizing the SATA power blade connector.

Further, the housing

270

of the PCB connector

24

may further include a user section receptacle

268

that includes a plurality of square pins

269

that are utilized to command a storage peripheral, such as a disk drive, to operate in a plurality of different modes. In the disk drive embodiment, the user section receptacle

268

is often used in disk drive testing. The square pins

269

of the user section receptacle

228

are connected to the PCB

13

.

Embodiments of the present invention for the various cable connectors and the PCB connector

24

also provide for pre-grounding (i.e. the dissipation of electro-static discharge (ESD)). As previously discussed, one or both of the guide arms

220

of the various disclosed cable connectors may include a conductive contact

237

such as a grounding clip.

As will be described in more detail later, the grounding contacts

237

of the guide arms may be coupled to ground conductors of the data and power shielded cables

272

,

275

connected inside of the data and power blade-receiving portions

212

,

225

, respectively, in order to effectuate various grounding configurations for pre-grounding. Further, one or both of guide arm receiving cavities

254

may include a conductive surface such as a grounding tab

264

(e.g. a metal grounding tab). Each grounding tab

264

is coupled to ground on the PCB

13

by a ground post

263

, respectively. Also, it should be appreciated that either the rectangular or oval shaped guide arm receiving cavities may include conductive surfaces for mating with a corresponding grounding contact of a corresponding rectangular or oval shaped guide arm.

Accordingly, as an example, when the cable connector

22

is mated to the PCB connector

24

, the conductive contacts

237

of the guide arms

220

will engage the grounding tabs

264

of the guide arm receiving cavities

254

providing pre-grounding to either one or both of the data and/or power blade-receiving portions

212

,

225

before they engage with the corresponding data and/or power blade connectors

206

,

228

. This of course applies to the other disclosed alternative embodiments of cable connector

22

such as power signal only cable connector

422

, data signal only cable connector

448

, power signal only cable connector

460

, and combined data and power signal cable connector

480

. Specific examples of this, related to the cable connector

22

as an example, will now be described.

However, in an alternative embodiment, the housing

210

and the guide arms

220

may be made from a conductive plastic material such that the cable connector

22

is conductive. Further, in one embodiment, the housing

270

of the PCB connector

24

may also be made from a conductive plastic material such that the PCB connector

24

is also conductive and can be grounded. In this way, when the conductive cable connector

22

is mated to the conductive PCB connector

24

, the guide arms

220

will first engage the guide arm receiving cavities

254

providing pre-grounding to either one or both of the data and/or power blade-receiving portions

212

,

225

before they engage with the corresponding data and/or power blade connectors

206

,

228

. This also applies to the other disclosed alternative embodiments of cable connector

22

such as power signal only cable connector

422

, data signal only cable connector

448

, power signal only cable connector

460

, and combined data and power signal cable connector

480

.

Various types of grounding configurations for pre-grounding will now be discussed. With reference now to

FIG. 6A

,

FIG. 6A

is a schematic diagram showing a pre-grounding configuration wherein both the data blade-receiving portion

212

and the power blade-receiving portion

225

of the cable connector

22

are configured for pre-grounding to the PCB connector

24

. A plurality of data SATA signal conductors

602

of the data SATA shielded cable

272

are shown, which are located in the data blade-receiving portion

212

and are connected to the data electrical contact arrangement

213

. Particularly, a ground conductor

604

is directly coupled to a grounding contact

237

(e.g. a ground clip) of one of the guide arms

220

for pre-grounding (i.e. electro-static discharge (ESD)). This is shown as line

606

(ESD-1). Further, a plurality of power SATA signal conductors

610

of the power SATA shielded cable

274

are shown, which are located in the power blade-receiving portion

225

and are connected to the power electrical contact arrangement

232

. Particularly, a ground conductor

612

is directly coupled to a grounding contact

237

(e.g. a ground clip) of one of the guide arms

220

for pre-grounding (i.e. electro-static discharge (ESD)). This is shown as line

608

(ESD-1).

Accordingly, when the cable connector

22

is mated to the PCB connector

24

, the grounding contacts

237

of the guide arms

220

will engage the grounding tabs

264

of the guide arm receiving cavities

254

providing pre-grounding to the data and power blade-receiving portions

212

,

225

before they engage with the corresponding data and power blade connectors

206

,

228

. Alternatively, in the conductive cable connector and PCB connector embodiment, the ground conductors may just be coupled to the guide arms to provide pre-grounding. Further, it should be appreciated that this grounding configuration for pre-grounding is also applicable to other disclosed alternative embodiments of cable connectors such as the combined data and power signal cable connector

480

.

With reference now to

FIG. 6B

,

FIG. 6B

is a schematic diagram showing a pre-grounding configuration wherein the data blade-receiving portion is not present and the power blade-receiving portion

225

of the cable connector

22

is configured for pre-grounding to the PCB connector

24

. A plurality of power SATA signal conductors

610

of the power SATA shielded cable

274

are shown, which are located in the power blade-receiving portion

225

and are connected to the power electrical contact arrangement

232

. Particularly, a first ground conductor

611

is directly coupled to a grounding contact

237

(e.g. a ground clip) of one of the guide arms

220

for pre-grounding (i.e. electro-static discharge (ESD)), which is shown as line

612

(ESD-1). Further, a second ground conductor

613

is directly coupled to a grounding contact

237

(e.g. a ground clip) of one of the guide arms

220

for pre-grounding (i.e. electro-static discharge (ESD)), which is shown as line

614

(ESD-2). Accordingly, when the cable connector

22

is mated to the PCB connector

24

, the grounding contacts

237

of the guide arms

220

will engage the grounding tabs

264

of the guide arm receiving cavities

254

providing pre-grounding for the power blade-receiving portion

225

before it engages with the corresponding power blade connector

228

. Alternatively, in the conductive cable connector and PCB connector embodiment, the ground conductors may just be coupled to the guide arms to provide pre-grounding. Further, it should be appreciated that this grounding configuration for pre-grounding is also applicable to other disclosed alternative embodiments of cable connectors such as the power signal only cable connector

422

and the power signal only cable connector

460

.

Looking now at

FIG. 6C

,

FIG. 6C

is a schematic diagram showing a pre-grounding configuration wherein the power blade-receiving portion is not present and the data blade-receiving portion

212

of the cable connector

22

is configured for pre-grounding to the PCB connector

24

. A plurality of data SATA signal conductors

602

of the data SATA shielded cable

272

are shown, which are located in the data blade-receiving portion

212

and are connected to the data electrical contact arrangement

213

. Particularly, a first ground conductor

621

is directly coupled to a grounding contact

237

(e.g. a ground clip) of one of the guide arms

220

for pre-grounding (i.e. electro-static discharge (ESD)), which is shown as line

622

(ESD-1). Further, a second ground conductor

623

is directly coupled to a grounding contact

237

(e.g. a ground clip) of one of the guide arms

220

for pre-grounding (i.e. electro-static discharge (ESD)), which is shown as line

624

(ESD-2). Accordingly, when the cable connector

22

is mated to the PCB connector

24

, the grounding contacts

237

of the guide arms

220

will engage the grounding tabs

264

of the guide arm receiving cavities

254

providing pre-grounding for the data blade-receiving portion

225

before it engages with the corresponding data blade connector

206

. Alternatively, in the conductive cable connector and PCB connector embodiment, the ground conductors may just be coupled to the guide arms to provide pre-grounding. Further, it should be appreciated that this grounding configuration for pre-grounding is also applicable to other disclosed alternative embodiments of cable connectors such as the data signal only cable connector

448

.

Turning now to

FIG. 6D

,

FIG. 6D

shows the layout of the data and power signal contacts of the data and power blade connectors

206

,

228

of the PCB connector

24

onto the PCB

13

and further shows grounding tabs

264

of the guide arm receiving cavities

254

coupled to ground on PCB

13

. It should be appreciated that the grounding tabs

264

could also be coupled to a ground at another location. For example, in the disk drive embodiment, the grounding tabs could be coupled to the grounded chassis of the disk drive.

It should be appreciated by those skilled in the art that although embodiments of the invention for cable connectors have been presented having only one data blade-receiving portion, only one power blade-receiving portion, and only one data and one power blade-receiving portion that a wide variety of cable connectors having multiple types of blade-receiving portions such as: multiple data blade-receiving portions, multiple power blade-receiving portions, and multiple data and power blade-receiving portions, as well as other types-of blade-receiving portions are deemed to lie within the spirit and scope of the invention.

It should further be appreciated by those skilled in the art that although embodiments of the invention for cable connectors and PCB connectors have been illustrated for use with storage peripherals, such as disk drives, utilizing a SATA standard, such as the Serial ATA: High Speed Serialized AT Attachment standard or the Serial Attached Small Computer System Interface (SAS) standard, that numerous alternative types of cable connectors and PCB connectors for various types of electronic devices utilizing differing type standards are deemed to lie within the spirit and scope of the invention.

Number	Name	Date	Kind
4842543	Davis	Jun 1989	A
5199884	Kaufman et al.	Apr 1993	A
5356300	Costello et al.	Oct 1994	A
5466171	Bixler et al.	Nov 1995	A
5620329	Kidd et al.	Apr 1997	A
5885088	Brennan et al.	Mar 1999	A
6053761	Baron et al.	Apr 2000	A
6071141	Semmeling et al.	Jun 2000	A
6093046	Chiou et al.	Jul 2000	A
6234817	Hwang	May 2001	B1
6290530	Chang	Sep 2001	B1
6331122	Wu	Dec 2001	B1
6402552	Wagner	Jun 2002	B1
6422892	Chen et al.	Jul 2002	B1
6447340	Wu	Sep 2002	B1
6561836	Marshall et al.	May 2003	B1
6565390	Wu	May 2003	B2
20020055292	Maiers et al.	May 2002	A1

Robust serial advanced technology attachment (SATA) cable connector

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Term Extension

Abstract

Description

Claims

US Referenced Citations (18)

Non-Patent Literature Citations (1)